The present invention relates to a liposome having a sugar chain bonded to its membrane surface, preferably through a linker protein, and having excellent qualities in intestinal absorption, and to a liposome product comprising a drug or a gene encapsulated in the sugar-modified liposome. The liposome product may be used in preparations comprising medicinal drugs, cosmetics and other various products in the medical/pharmaceutical fields, and it is particularly useful in a therapeutic drug delivery system that specifically targets selected cells or tissues, such as cancer cells, and in the delivery of drugs or genes locally to a selected region, and in a diagnostic cell/tissue sensing probe.
The present invention further relates to a liposome modified by a sugar chain excellent in intestinal absorption and a liposome preparation prepared by encapsulating a liposome having a medicinal drug and a gene therein.
The realization of a “drug delivery system (DDS) for delivering drugs or genes intentionally and intensively to cancer cells or target tissues” has been set as one of the specific goals of the U.S. National Nanotechnology Initiative (NNI). The Nanotechnology/Materials Strategy of the Council for Science and Technology Policy in Japan also focuses research on “Medical micro systems/materials, Nanobiology for utilizing and controlling biological mechanisms,” and one of the five year R & D targets is “Establishment of basic seeds in health/life-lengthening technologies such as biodynamic materials and pinpoint treatments.” However, even in view of these goals the incidence and morbidity of cancers become higher year after year, along with a progressive aging of the population, and a serious need for the development of a targeting DDS material which is a novel treatment material exists.
Targeting DDS nano-structured materials for other diseases also come under the spotlight because they have no side effects, and their market size of over 10 trillion yen is anticipated in the near future. Further, it is expected that these materials will be utilized in medical diagnosis as well as medical treatments.
The therapeutic effect of a drug will be achieved only if the drug reaches a specific target region and acts thereupon. If the drug reaches a non-target region, undesirable side effects may result. Thus, the development of a drug delivery system that allows drugs to be used effectively and safely is also desired. In a drug delivery system, the targeting DDS can be defined as a concept of delivering a drug to a “necessary region in a body,” in a “necessary amount” and for a “necessary time-period.” A liposome is a noteworthy particulate carrier regarded as a representative material for a targeting DDS. While a passive targeting method based on modification of lipid type, composition ratio, size, or surface charge of liposomes has been developed to impart a targeting function to this particle, this method is still insufficient and required to be improved in many respects.
An active targeting method has also been researched in an attempt to achieve a sophisticated targeting function. While the active targeting method referred to as a “missile drug” is conceptually ideal, it has not been accomplished in Japan and abroad, and future developments are expected. This method is designed to provide ligands bonded to the membrane surface of a liposome that will be specifically recognized and bound by a receptor residing on the cell-membrane surface of a target tissue, thereby achieving active targeting. The cell-membrane surface receptor ligands include antigens, antibodies, peptides, glycolipids, and glycoproteins.
It is revealing that the sugar chain of glycolipids and glycoproteins bears an important role as an information molecules in various communications between cells, such as in the creation or morphogenesis of tissues, in the proliferation or differentiation of cells, in the biophylaxis or fecundation mechanism, and in the creation and metastasis of cancers.
Further, research on various types of lectins (sugar-recognizing protein) such as selectin, siglec and galectin, which serve as receptors on cell-membrane surfaces of target tissues, has been proposed to serve as receptors for sugar chains having different molecular structures that may be used as noteworthy new DDS ligands (Yamazaki, N., Kojima, S., Bovin, N. V., Andre, S., Gabius, S. and H.-J. Gabius. Adv. Drug Delivery Rev. 43:225-244 (2000); Yamazaki, N., Jigami, Y., Gabius, H.-J., and S. Kojima. Trends in Glycoscience and Glycotechnology 13:319-329 (2001)).
Liposomes having ligands bonded to their external membrane surface have been actively researched in order to provide a DDS material for delivering drugs or genes selectively to a target region, such as cancer. While these liposomes bind to target cells in vitro, most of them do not exhibit adequate targeting to intended target cells or tissues in vivo (Forssen, E. and M. Willis. Adv. Drug Delivery Rev. 29:249-271 (1998); Takahashi, T. and M. Hashida. Today's DDS/Drug Delivery System, Iyaku Journal Co., Ltd. (Osaka, Japan), 159-167 (1999)). While some research has been conducted on liposomes incorporating glycolipids having sugar chains, for use as a DDS material, these liposomes were evaluated only in vitro, and little progress has been reported for similar research on liposomes incorporating glycoproteins having sugar chains (DeFrees, S. A., Phillips, L., Guo, L. and S. Zalipsky. J. Am. Chem. Soc. 118:6101-6104 (1996); Spevak, W., Foxall, C., Charych, D. H., Dasqupta, F. and J. O. Nagy. J. Med. Chem. 39:1918-1020 (1996); Stahn, R., Schafer, H., Kernchen, F. and J. Schreiber. Glycobiology 8:311-319 (1998); Yamazaki, N., Jigami, Y., Gabius, H.-J., and S. Kojima. Trends in Glycoscience and Glycotechnology 13:319-329 (2001)). As above, systematic research into liposomes having a wide variety of sugar chains, on the glycolipids or glycoproteins bonded to the liposomes, including preparative methods and in vivo analyses thereof, is pending and represents an important challenge to be progressed in future.
Further, in research on new types of DDS materials, it is an important challenge to develop a DDS material capable of being orally administered in the easiest and cheapest way. For example, when a peptide medicine is orally administered, it is subject to enzymolysis and may be only partially absorbed in the intestine due to its water solubility, high molecular weight, and low permeability in the mucosa of small intestine. As an alternative, a ligand-bonded liposome is getting attention as a potential DDS material for delivering high molecular-weight medicines or genes into the blood stream through the intestine (Lehr, C.-M. J. Controlled Release 65:19-29 (2000)). However, results from research into an intestinal absorption-controlled liposome, using a sugar chain as the ligand, have not been reported.
It is therefore an object of the present invention to provide a sugar-modified liposome that is specifically recognized and bound by selected lectins (sugar-recognizing proteins) residing on the surface of target cells and tissues, and having excellent qualities of absorption, particularly in the intestine. It is a further object of the present invention to provide a liposome product comprising a drug or gene encapsulated by a sugar-modified liposome that is recognized by cells or tissues in vivo, and that can specifically deliver drugs or genes to target cells or tissues.
In order to meet the challenges mentioned above, various experimental tests and studies have been conducted on the properties of liposome surfaces, and on the sugar chains and linker proteins used to bond the sugar chains to the surface of liposomes. Through this research, it has been shown that the targeting performance of sugar-modified liposomes to particular target tissues can be controlled by the sugar chain structure. It has also been shown that the amount of liposome transferred to each target tissue can be increased by hydrating the liposome surface and/or the linker protein, resulting in more effective delivery of drugs or genes to each of the target cells or tissues.
According to a first aspect of the present invention, there is provided a liposome having a sugar chain bonded to the liposome membrane surface.
According to a second aspect of the present invention, there is provided a liposome having a sugar chain bonded to the liposome membrane surface, and further comprising tris(hydroxymethyl)aminomethane bonded to the liposome membrane surface.
According to a third aspect of the present invention, there is provided a liposome having a sugar chain bonded to the liposome membrane surface through a linker protein.
According to a fourth aspect of the present invention, there is provided a liposome having a sugar chain bonded to the liposome membrane surface through a linker protein, wherein both the liposome membrane surface and the linker protein are hydrophilized.
According to a fifth aspect of the present invention, there is provided a liposome product comprising the sugar-modified liposome according to any one of the first to fourth aspects of the present invention, and a drug or gene encapsulated in the sugar-modified liposome.
In each aspect of the present invention, the sugar chain is preferably selected from the group consisting of lactose disaccharide, 2′-fucosyllactose trisaccharide, difucosyllactose tetrasaccharide, 3-fucosyllactose trisaccharide, Lewis X trisaccharide, sialyl Lewis X tetrasaccharide, 3′-sialyllactosamine trisaccharide, and 6′-sialyllactosamine trisaccharide.
In each aspect of the present invention, preferably an adjusted amount of the sugar chain is bonded to the membrane surface of the liposome.
In each relevant aspect of the present invention, preferably the surface of the liposome and/or the linker protein is hydrophilized. Preferably, the hydrophilization is performed by using tris(hydroxymethyl)aminomethane.
In each relevant aspect of the present invention, the linker protein is preferably human serum albumin or bovine serum albumin.
Further, an object of the present invention is to provide a liposome to which a sugar chain bonded, the sugar chain having a specific binding activity to various types of lectins (sugar chain recognition protein) present in cell surfaces of various types of tissues, and the liposome being capable of recognizing cells and tissues in vivo, thereby efficiently delivering a medicinal drug or a gene to the cells and tissues. Another object of the present invention is to provide a therapeutic drug containing the liposome. Still another object of the present invention is to provide a highly stable liposome.
To attain the objects mentioned above, the present inventors have conducted studies on the composition of a liposome. As the result, they obtained a highly stable liposome. They further conducted various experimental studies on the type and binding density of the sugar chain to be bonded to the surface of a liposome, linker proteins and a compound hydrophilizing the liposome. As a result, they found that the accuracy of targeting of a liposome to each tissue is actually and successfully controlled by the structure of a sugar chain. In addition, they found that the amount of liposome delivered to each tissues is successfully increased by hydrating a liposome surface and/or a linker protein with a predetermined hydrophilic compound and further controlling the density of a sugar chain to be bonded to the liposome, thereby attaining efficient delivery of a medicinal drug or a gene to a target cell and tissue. Based on these findings, they accomplished the present invention.
The present inventors further conducted intensive studies on application of the liposome obtained in this manner to practical therapy for a disease. As a result, they found that such a liposome is successfully applied to treatments for various diseases of tissues and organs by varying the type of sugar chain bonded onto the surface of the liposome. Based on the finding, they accomplished the present invention.
The present invention will now be described in detail.
A liposome generally means a closed vesicle consisting of a lipid layer formed as a membrane-like aggregation, and an inner water layer.
As shown in FIGS. 1 to 8, a liposome of the present invention includes a liposome with a sugar chain covalently bonded to its membrane surface or its lipid layer through a linker protein such as human serum albumin. While only a single sugar chain-linker protein set, bonded to the liposome, is illustrated in FIGS. 1 to 8, these figures (including
The liposomes of the present invention are modified by a sugar chain. Preferred examples of the sugar chains include lactose disaccharide (Gal. beta. 1-4 Glc) shown in
In the present invention, it is preferred to bond the sugar chain to the membrane surface of the liposome through a linker protein. Such liposome structures are shown in FIGS. 1 to 8, together with the chemical structures of the sugar chain.
The linker protein may be an animal serum albumin, such as human serum albumin (HSA) or bovine serum albumin (BSA). In particular, it has been verified through experimental tests using mice that a liposome complex using human serum albumin is taken into target tissues in a greater amount than a liposome complex using a different linker protein.
The lipid constituting the liposomes of the present invention includes phosphatidylcholines, phosphatidylethanolamines, phosphatidic acids, gangliosides, glycolipids, phosphatidylglycerols, and cholesterol. The phosphatidylcholines preferably include dimyristoylphosphatidylcholine, dipalmitoylphosphatidylcholine, and distearoylphosphatidylcholine. The phosphatidylethanolamines preferably include dimyristoylphosphatidylethanolamine, dipalmitoylphosphatidylethanolamine, and distearoylphosphatidylethanolamine. The phosphatidic acids preferably include dimyristoylphosphatidic acid, dipalmitoylphosphatidic acid, distearoylphosphatidic acid, and dicetylphosphoric acid. The gangliosides preferably include ganglioside GM1, ganglioside GD1a, and ganglioside GT1b. The glycolipids preferably include galactosylceramide, glucosylceramide, lactosylceramide, phosphatide, and globoside. The phosphatidylglycerols preferably include dimyristoylphosphatidylglycerol, dipalmitoylphosphatidylglycerol, and distearoylphosphatidylglycerol.
While a regular liposome may be used in the invention, it is preferable to hydrophilize the surface of the liposome.
The liposome itself can be produced through any conventional method including a thin film method, a reverse phase evaporation method, an ethanol injection method, and a dehydration-rehydration method.
The particle size of the liposome can be controlled through an ultrasonic radiation method, an extrusion method, a French press method, a homogenization method or any other suitable conventional method.
A specific method of producing the liposome itself of the present invention will be described below. For example, a mixed micelle is first prepared by mixing a compounded lipid consisting of phosphatidylcholines, cholesterol, phosphatidylethanolamines, phosphatidic acids, and gangliosides or glycolipids or phosphatidylglycerols, with sodium cholic acid serving as a surfactant. Particularly, the phosphatidylethanolamines are essentially compounded to provide a hydrophilic reaction site, and the composition of gangliosides or glycolipids or phosphatidylglycerols are essentially compounded to provide a bonding site for the linker protein.
The obtained mixed micelle is subjected to ultrafiltration to prepare a liposome. Then, the membrane surface of the liposome is hydrophilized by applying a bivalent crosslinking reagent and tris(hydroxymethyl)aminomethane onto the lipid phosphatidylethanolamine of the membrane of the liposome.
The liposome can be hydrophilized through a conventional method such as a method of producing a liposome by using phospholipids covalently bonded with polyethylene glycol, polyvinyl alcohol, maleic anhydride copolymer or the like (Japanese Patent Laid-Open Publication No. 2001-302686). However, in the present invention, it is particularly preferable to hydrophilize the liposome membrane surface by using tris(hydroxymethyl)aminomethane.
The technique using tris(hydroxymethyl)aminomethane has some advantages superior to the conventional method of using polyethylene glycol or the like. For example, when a sugar chain is bonded onto a liposome and the molecular recognition function of the sugar chain is utilized for bringing about the targeting performance as in the present invention, the tris(hydroxymethyl)aminomethane is particularly preferable because it is a substance having a low molecular weight. More specifically, as compared to the conventional method using a substance having a high molecular weight such as polyethylene glycol, the tris(hydroxymethyl)aminomethane is less apt to become a three-dimensional obstacle to the sugar chain and to prevent the lectin (sugar-recognizing protein) on the membrane surface of target cells from recognizing the sugar-chain molecule.
In addition, the liposome according to the present invention is excellent in terms of particle-size distribution, composition, and dispersing characteristics, as well as in long-term storage stability and in vivo stability, even after the above hydrophilization, and thereby is suitable for forming into and using as a liposome product.
As an example of the process for forming of a liposome hydrophilized through the use of tris(hydroxymethyl)aminomethane, a bivalent reagent is added to a liposome solution. Exemplary bivalent reagents include bissulfosuccinimidylsuberate, disuccinimidylglutarate, dithiobissuccinimidylpropionate, disuccinimidylsuberate, 3,3′-dithiobissulfosuccinimidylpropionate, ethylene glycol bissuccinimidylsuccinate, or ethylene glycol bissulfosuccinimidylsuccinate. Exemplary lipids include dimyristoylphosphatidylethanolamine, dipalmitoylphosphatidylethanolamine, and distearoylphosphatidylethanolamine. Upon combination, a reaction between the bivalent reagent and the lipid occurs so as to bond the bivalent reagent to the lipid on the membrane of the liposome. Then, the tris(hydroxymethyl)aminomethane is reacted with the bivalent reagent to bond the tris(hydroxymethyl)aminomethane to the liposome surface.
In the present invention, the sugar chain may be bonded to the liposome through a linker protein. The linker protein is first bonded to the liposome by first treating the liposome with an oxidant such as NaIO4, Pb(O2CCH3)4, or NaBiO3 to oxidize the gangliosides residing on the membrane surface of the liposome. The linker protein is then bonded to the gangliosides on the liposome membrane surface by a reductive amination reaction using a reagent such as NaBH3CN or NaBH4.
Preferably, the linker protein is also hydrophilized by bonding a moiety having a hydroxy group to the linker protein. For example, tris(hydroxymethyl)aminomethane may be bonded to the linker protein on the liposome by using a bivalent reagent such as bissulfosuccinimidylsuberate, disuccinimidylglutarate, dithiobissuccinimidylpropionate, disuccinimidylsuberate, 3,3′-dithiobissulfosuccinimidylpropionate, ethylene glycol bissuccinimidylsuccinate, or ethylene glycol bissulfosuccinimidylsuccinate, as discussed above.
One of the ends of a bivalent crosslinking reagent is bonded to the amino groups of the linker protein. Then, the reduction terminals of desired types of sugar chains are glycosylaminated to prepare a sugar-chain glycosylamine compound, and the amino groups of the obtained sugar chains are bonded to a part of the other unreacted ends of the bivalent crosslinking reagent bonded to the linker protein on the liposome.
Then, the surface of the resulting linker protein which resides on the membrane surface of the liposome has the sugar chain bonded thereto and is hydrophilized by using the mostly remaining unreacted ends of the bivalent reagent to which no sugar chain is bonded. That is, a bonding reaction is caused between the unreacted ends of the bivalent reagent bonded to the linker protein on the liposome and tris (hydroxymethyl)aminomethane, so as to hydrophilize the liposome surface to obtain the liposome according to the present invention.
The hydrophilization of the liposome surface and the linker protein provides enhanced mobility toward various tissues and enhanced sustainability in various tissues. This advantage is realized because the hydrophilized liposome surface and linker protein become hydrated by water molecules in vivo or in a blood vessel, which allows a portion of the liposome complex, other than the sugar chain, to function as if it is a layer of water which is not recognized by the various tissues. The liposome complex is thus not recognized by any tissues other than target tissues and only through the sugar chain is recognized by the lectin (sugar-recognizing protein) of the target tissues.
As a next general step in the production of the sugar-modified liposomes of the present invention, the sugar chain is bonded to the linker protein on the liposome. For this purpose, the reduction terminal of the sugars constituting the sugar chain is, for example, glycosylaminated by using ammonium salts such as NH4HCO3 or NH2COONH4, and then the linker protein bonded onto the liposome membrane surface is bonded to the above glycosylaminated sugars using a bivalent reagent such as bissulfosuccinimidylsuberate, disuccinimidylglutarate, dithiobissuccinimidylpropionate, disuccinimidylsuberate, 3,3′-dithiobissulfosuccinimidylpropionate, ethylene glycol bissuccinimidylsuccinate, or ethylene glycol bissulfosuccinimidylsuccinate to obtain the liposomes shown in
The sugar-modified liposomes of the present invention generally exhibit significantly high intestinal absorption. In addition, the intestinal absorption of the liposomes can be controlled by adjusting the density of the sugar chains bonded to the liposome, so that the liposome can more efficiently deliver drugs to target regions with reduced side effects. For example, FIGS. 10 to 13 show the results of studies performed to determine the rates of distribution (or intestinal absorption) of four different sugar-modified liposomes from intestine to blood, where the amount of sugar chain bonded to the respective liposomes is changed in three levels.
In these experiments, the amount of sugar chain bonded to the respective liposomes is changed by bonding the sugar chain to the linker protein-bonded liposome at three density levels: (1) 50 μg, (2) 200 μg, and (3) 1 mg. As shown in the Figures, when lactose disaccharide is used as the sugar chain, the intestinal absorption is gradually lowered as the density of the sugar chain is increased. By contrast, when 2′-fucosyllactose trisaccharide or difucosyllactose tetrasaccharide is used as the sugar chain, the intestinal absorption is increased as the density of the sugar chain is increased. When 3-fucosyllactose trisaccharide is used as the sugar chain, the intestinal absorption is lowered and then increased as the density of the sugar chain is increased.
These characteristics show that intestinal absorption is altered by the amount of sugar chain bonded to the liposome for each type of sugar chain. Thus, intestinal absorption can be controlled by appropriately selecting the amount and type of sugar chain bonded to the liposome.
The results from additional experiments demonstrate that the type and amount of sugar chain bonded to the surface of the sugar-modified liposomes of the present invention can directly effect the targeting performance of the liposomes to particular target cells or tissues. The results of these experiments are shown in FIGS. 14 to 21.
For example, it is evident from the results that liposomes (LX, SLX, 3SLN, 6SLN) modified by four types of sugar chains: Lewis X trisaccharide, sialyl Lewis X tetrasaccaride, 3′-sialyllactosamine trisaccharide, and 6′-sialyllactosamine trisaccharide, generally have a high targeting performance to cancer tissues and inflammatory tissues (
The liposome product obtained by encapsulating drugs or genes for therapeutic or diagnostic purposes, using the sugar-modified liposomes of the present invention, would also have a targeting performance selectively controlled by the amount and identity of the sugar chains bonded to the liposome. Thus, the liposome product of the present invention can be used to provide enhanced delivery of therapeutic drugs or diagnostic agents to target cells and tissues, as well as to suppress side effects by reducing the ability of drugs to be taken into non-target cells and tissues.
Drugs, such as cancer drugs, or genes, such as those used in gene therapy, may be encapsulated in the sugar-modified liposomes of the present invention through any suitable conventional method including a method of forming the liposome by using a solution including the drugs or genes, and a lipid such as a phosphatidylcholines or phosphatidylethanolamines.
Further, the present invention is directed to a targeting liposome and an intestinal-absorption controlled liposome having various sugar chains on the surface. In the present invention, the term “targeting” refers to an ability of a substance to reach a specific target site such as a predetermined tissue, organ, or a lesion e.g., cancer, when the substance is injected in vivo and then to be taken up by the site. The term “intestinal-absorption controlled” refers to a nature of a substance of being absorbed in vivo via the intestinal tract, in other words, “absorbability from the intestinal tract”, which further includes a property of controlling the absorption rate and degree.
The “liposome” generally refers to a closed vesicle composed of a lipid layer, which is a membrane-form lipid assembly and an aqueous layer formed in the lipid layer. The liposome of the present invention has sugar chains bonded onto surface, that is, the lipid layer, as shown in
Various types of sugar chains may be used depending upon the tissue, organ or cancer to which an intestinal-absorption controlled liposome and a targeting liposome according to the present invention are targeted.
It is known that E-selectin and P-selectin, which express on the vascular endothelial cells of a lesion, strongly bind to sialyl Lewis X, which is a sugar chain expressing on the cellular membrane of leukocytes. To the liposome of the invention, the sialyl Lewis X sugar chain or an analogous sugar chain, which is reactive to a protein such as a lectin (e.g., E-selectin, P-selectin) having a sugar chain binding site, is bonded while being limited in type and density. It is considered that the liposomes are specifically accumulated to a lesional site such as cancer whose vascular endothelial cells express E-selectin and P-selectin. In the sites expressing E-selectin and P-selectin, inflammation and vascularization take place. In the blood vessel of these sites, the intercellular space of the endothelial cells is enlarged. Therefore, the accumulated liposomes are conceivably diffused from the intercellular space to the lesional site and its peripheral region. The liposomes thus diffused are taken up (through endocytosis) by the cells of the lesional site and the peripheral region and intracellularly release a drug encapsulated therein. In this mechanism, the liposomes produce an effect on inflammatory diseases or cancer.
As the sugar chain to be bonded to the liposome of the present invention, mention may be made of a sugar chain reactive to a protein, such as E-selectin and P-selectin, having a sugar chain binding site as mentioned above. The E-selectin and P-selectin herein refer to various types of lectins (sugar-chain recognizing proteins), which include C-type lectins such as selectin, DC-SIGN, DC-SGNR, colectin, mannose binding protein, 1-type lectins such as siglec, P-type lectins such as a mannose-6-phosphate receptor, R-type lectin, L-type lectin, M-type lectin, and galectin. The target cells to which the liposome of the present invention is directed vary in type of protein, such as lectin, having a sugar-chain binding site expressing depending upon the cells. Therefore, a liposome capable of targeting specifically to a predetermined cell can be obtained by selecting a type of sugar chain depending upon the type of protein.
Examples of the intestinal-absorption controlled liposome include 3′-sialyllactose trisaccharide (whose structure is shown in
The present inventors have made an effort intensively with a view to improving membrane stability of the liposome to be used in the present invention, preventing leakage of a medicinal drug and a gene encapsulated in the liposome, hydrophilizing the membrane surface of the liposome, binding a protein with various densities, and binding a sugar chain with various densities. As a result, they prepared liposomes constituted of various lipids and glycolipids as mentioned below. Examples of the lipids constituting the liposome of the present invention include phosphatidylcholines, phosphatidylethanolamines, phosphatidic acids, long-chain alkyl phosphates, dicetyl phosphate, gangliosides, glycolipids, phosphatidylglycerols, sphingomyelins, and cholesterols. Examples of the phosphatidylcholines preferably include dimyristoylphosphatidylcholine, dipalmitoylphosphatidylcholine, and distearoylphosphatidylcholine. Examples of phosphatidylethanolamines preferably include dimyristoylphosphatidyl ethanolamine, dipalmitoylphosphatidylethanolamine, and distearoyl phosphatidylethanolamine. Examples of the phosphatidic acids or long-chain alkyl phosphates preferably include dimyristoylphosphatidic acid, dipalmitoylphosphatidic acid, distearoylphosphatidic acid, and dicetylphosphoric acid. Examples of the gangliosides preferably include ganglioside GM1, ganglioside GD1a, and ganglioside GT1b. Examples of glycolipids preferably include galactosylceramide, glycosylceramide, lactosylseramide, phosphatide, and globoside. Examples of the phosphatidylglycerols preferably include dimyristoylphosphatidylglycerol, dipalmitoylphosphatidylglycerol, and distearoylphosphatidylglycerol. Of them, a phosphatidic acid, a long-chain alkyl phosphate, ganglioside, glycolipid, or cholesterol is desirably added as a constitutional lipid since they have an effect of increasing stability of a liposome.
Examples of the lipid constituting the liposome of the present invention include not less than one lipid (0 to 30% by mole) selected from the group consisting of phosphatidylcholines (O to 70% by mole), phosphatidylethanolamines (0 to 30% by mole), phosphatidic acids, long-chain alkyl phosphates and dicetyl phosphates; not less than one lipid (O to 40% by mole) selected from the group consisting of gangliosides, glycolipids, phosphatidylglycerols, and sphingomyelins; and cholesterols (O to 70% by mole). The liposome itself can be produced in accordance with a customary method. Examples of such a customary method include a thin-film method, reverse layer vaporization method, ethanol injection method, and dehydration-rehydration method.
Furthermore, the particle diameter of a liposome may be controlled by an ultrasonic irradiation method, extrusion method, French press method, or homogenization method. A method of producing the liposome of the present invention will be more specifically described. First, a mixed micelle is prepared by a lipid containing components such as a phosphatidylchlorin, cholesterol, a phosphatidylethanolamine, phosphatidic acid, ganglioside, glycolipid or phosphatidylglycerol, and sodium cholate serving as a surfactant.
Of them, addition of a phosphatidic acid or a long-chain alkyl phosphate such as dicetylphosphate is essential to negatively charge a liposome. Addition of a phosphatidylethanolamine is essential for a hydrophilic reaction site. Addition of a ganglioside, glycolipid or phosphatidylglycerol is essential for a binding site of a linker protein. At least one lipid selected from the group consisting of gangliosides, glycolipids, phosphatidylglycerols, sphingomyelins and cholesterols assembles in a liposome and functions as a scaffold (raft) for biding a linker protein thereto. The liposome of the present invention is further stabilized by forming such a raft to which a protein is to be bonded. In other words, the present invention includes a liposome in which a raft is formed of at least one lipid selected from the group consisting of gangliosides, glycolipids, phosphatidylglycerols, sphingomyelins and cholesterols to bind a linker protein thereto.
The mixed micelle thus obtained is subjected to ultrafiltration to prepare a liposome.
As the liposome to be used in the present invention, a general liposome may be used. However, the surface of the liposome is desirably hydrophilized. After a liposome is prepared as described above, the surface of the liposome is hydrophilized. The hydrophilization of the liposome surface is performed by binding a hydrophilic compound thereto. As a compound that may be used in hydrophilization, use may be made of a low molecular weight hydrophilic compound, preferably a low molecular weight hydrophilic compound having at least one OH group, more preferably, a low molecular weight hydrophilic compound having at least two OH groups. Furthermore, mention may be made of a low molecular weight hydrophilic compound having at least one amino group, in other words, a hydrophilic compound having at least one OH group and at least one amino group. Since a hydrophilic compound has a low molecular weight, it rarely causes steric hindrance to a sugar chain and thus does not prevent proceeding of a sugar-chain molecular recognition reaction by a lectin on the surface of a target cell membrane. Furthermore, examples of the hydrophilic compound do not include a sugar chain capable of binding a lectin used for targeting to a specific target such as a lectin in the sugar chain modified liposome of the present invention. As an examples of such a hydrophilic compound, use may be made of amino alcohols such as tris(hydroxyalkyl)aminoalkane including tris(hydroxymethyl)aminomethane, more specifically, tris(hydroxymethyl)aminoethane, tris(hydroxyethyl)aminoethane, tris(hydroxypropyl)aminoethane, tris(hydroxymethyl)aminomethane, tris(hydroxyethyl)aminomethane, tris(hydroxypropyl)aminomethane, tris(hydroxylmethyl)aminopropane, tris(hydroxyethyl)aminopropane, and tris(hydroxypropyl)aminopropane. Furthermore, a low molecular weight compound having an OH group to which an amino group is introduced may be used as a hydrophilic compound according to the present invention. Such a compound is not limited and, for example, cellobiose may be mentioned which has an amino group introduced into a sugar chain to which a lectin is not bonded. The surface of a liposome is hydrophilized by applying a divalent crosslinking agent and tris(hydroxymethyl)aminomethane onto a lipid, phosphatidylethanolamine of a liposome membrane. A hydrophilic compound is represented by the following general formulas (1), (2) and (3).
X—R1(R2OH)n Formula (1)
H2N—R3-(R4OH)n Formula (2)
H2N—R5(OH)n Formula (3)
In the formula, R1, R3 and R5 represent a linear or branched hydrocarbon chain of C1 to C40, preferably C1 to C20, further preferably C1 to C10; and R2 and R4 are absent or represent a linear or branched hydrocarbon chain of C1 to C40, preferably C1 to C20, further preferably C1 to C10. X represents a reactive functional group directly binding to a liposome lipid or a divalent crosslinking agent. Examples of such a functional group include COOH, NH, NH2, CHO, SH, NHS-ester, maleimide, imidoester, active halogen, EDC, pyridyldisulfide, azidephenyl, and hydrazide. A reference symbol n represents a natural number.
The surface of a liposome hydrophilized by such a hydrophilic compound is covered with a thin layer of the hydrophilic compound. However, since the thickness of the cover layer of the hydrophilic compound is low, even in the case of a liposome having a sugar chain bonded thereto, the reactivity of the sugar chain is not suppressed.
The hydrophilization of a liposome may be performed by a method (JP Patent Publication (Kokai) No. 2000-302685) of producing a liposome by using a phospholipid, which is prepared by covalently bonding polyethylene glycol, polyvinyl alcohol and an anhydrous maleic acid copolymer.
Of them, hydrophilization of a liposome surface is particularly preferably performed by use of tris(hydroxymethyl)aminomethane.
The hydrophilization method using tris(hydroxymethyl)aminomethane of the present invention is preferable compared to a conventional method using polyethylene glycol in several points. For example, in the case of the present invention where targeting is performed by use of a molecular recognition function of a sugar chain which is bonded onto a liposome, tris(hydroxymethyl)aminomethane is particularly preferably used, since tris(hydroxymethyl)aminomethane is a low molecular weight substance compared to a conventionally used high molecular weight substance such as polyethylene glycol, it rarely causes steric hindrance to the sugar chain, and does not prevent proceeding of a sugar-chain molecular recognition reaction performed by a lectin (sugar chain recognizing protein) on the membrane surface of a target cell.
Furthermore, the liposome of the present invention has a satisfactory size distribution, composition, and dispersion properties after completion of the hydrophilization treatment, and excellent long-term storage stability and in-vivo stability. Therefore, the liposome of the present invention is preferably used for producing a preparation.
To hydrophilize a liposome surface by tris(hydroxymethyl)aminomethane, first a divalent reagent such as bissulfosuccinimidylsuberate, disuccinimidyl glutarate, dithiobissuccinimidylpropionate, disuccinimidylsuberate, 3,3′-dithiobissurfosuccinimidylpropionate, ethylene glycol bissuccinimidylsuccinate, or ethylene glycol bissulfosuccinimidylsuccinate, is added to a liposome solution, which is obtained in accordance with a customary method using a lipid such as dimyristoylphosphatidylethanolamine, dipalmitoylphosphatidyl ethanolamine, or distearoylphosphatidylethanolamine to react them, thereby bonding the divalent regent to the lipid such as dipalmitoylphosphatidyl ethanolamine on the liposome membrane; and then tris(hydroxymethyl)aminomethane is reacted with one of the bonds of the divalent reagent, thereby bonding tris(hydroxymethyl)aminomethane to the liposome surface.
The liposome hydrophilized in this manner is extremely stable in vivo. Since it has a long in vivo half-life, even if a targeting sugar chain having targetability is not bonded as described later, the liposome can be preferably used as a drug carrier in the drug delivery system. The present invention includes a liposome hydrophilized with a low molecular weight compound in its surface.
The present invention includes a liposome hydrophilized with a hydrophilic compound as mentioned above and having no sugar chain bonded thereto. Such a hydrophilized liposome is advantageous since the stability of the liposome itself is high and the recognition of a sugar chain by the liposome is enhanced when a sugar chain is bonded to it.
The liposome of the present invention has a constitutional lipid containing not less than one lipid (0 to 30% by mole) selected from the group consisting of phosphatidylcholines (0 to 70% by mole), phosphatidylethanolamines (0 to 30% by mole), phosphatidic acids, long-chain alkyl phosphates and dicetyl phosphates; and not less than one lipid (0 to 40% by mole) selected from the group consisting of gangliosides, glycolipids, phosphatidylglycerols, and sphingomyelins; and cholesterols (0 to 70% by mole).
The present invention includes a method of hydrophilizing a liposome by bonding a hydrophilic compound as mentioned above to a liposome. Furthermore, a hydrophilized liposome having no sugar chain bonded thereto is included. A targeting liposome or an intestinal tract absorbable liposome according to the present invention can be produced by bonding a sugar chain to the liposome having no sugar bonded thereto.
In the present invention, any one of the sugar chains mentioned above may be directly bonded to the liposome prepared in the aforementioned manner and further bonded to the liposome via a linker protein. In this case, the type of a sugar chain to be bonded to a liposome is not limited to a single type. A plurality of types of sugar chains may be bonded. The plurality of types of sugar chains may bind to different lectins commonly present on the cellular surface of the same tissue or organ or different lectins present on the cellular surface of different tissues and organs. If the former case of sugar chain is selected, the liposome can be surely directed to a predetermined target tissue or organ. If the latter case of sugar chain is selected, a single type of liposome can be directed to a plurality of targets. In this way, multi-purpose targeting liposome can be obtained.
To bind a sugar chain to a liposome, a linker protein and/or the sugar chain are mixed in producing the liposome, thereby bonding the sugar chain on the surface of the liposome while producing the liposome. Alternatively, it is rather desirable to separately prepare a liposome, linker protein and sugar chain(s) and then bind the linker protein and/or the sugar chain to the liposome after completion of liposome production. This is because the binding density of the sugar chains can be controlled by bonding a linker protein and/or a sugar chain to the liposome.
Direct binding of a sugar chain to a liposome can be performed by the method described below.
A liposome is produced by mixing a sugar chain in the form of a glycolipid or by binding a sugar chain to a phospholipid of a liposome after completion thereof while controlling the density thereof.
When a sugar chain is bonded by use of a linker protein, it is preferable to use a protein derived from the living body, in particular, a protein derived from a human. The protein derived from the living body is not particularly limited and includes a protein present in blood such as albumin, and a physiologically active substance present in vivo, such as animal serum albumin including human serum albumin (HSA) and bovine serum albumin (BSA). Particularly when human serum albumin is used, it has been experimentally confirmed to show a large uptake by mice tissues.
The liposome of the present invention is extremely stable and post treatment can be easily applied to the liposome. More specifically, a protein, a linker protein and a sugar chain can be easily bonded to the liposome after completion of the production thereof. Accordingly, a large amount of liposomes are produced, and then, various types of liposomes can be desirably produced by bonding different types of proteins, a linker protein(s) and a sugar chain(s) to the liposomes in accordance with the purposes.
To the liposome of the present invention, a sugar chain is bonded via a linker protein or directly to a lipid constituting the liposome. The liposome of the present invention has a conjugated polysaccharide ligand such as a glycolipid and glycoprotein and hydrophilized with a low molecular weight compound.
When a targeting liposome according to the present invention is used as a pharmaceutical drug as is described later, it must contain a compound having a medicinal effect. The compound having a medicinal effect is encapsulated in the liposome or bonded to the surface of the liposome. Alternatively, a protein having a medicinal effect may be used as a linker protein. In this case, such a protein may serve not only as a linker protein for bonding a liposome and a sugar chain but also the protein having a medicinal effect. As the protein having a medicinal effect, physiologically active proteins may be mentioned.
A sugar chain may be bonded to a liposome via a linker protein by the method mentioned below.
First, a protein is bonded to the surface of a liposome. The liposome is treated with an oxidizing agent such as NaIO4, Pb(O2CCH3)4, or NaBiO3 to oxidize a ganglioside present on the membrane surface of the liposome. Then, the linker protein is bonded to the ganglioside on the liposome surface by a reductive amination using a reagent such as NaBH3CN or NaBH4. It is preferable that the linker protein is also hydrophilized by bonding a compound having a hydroxyl group to the linker protein. More specifically, a compound such as tris(hydroxymethyl)aminomethane for use in hydrophilization mentioned above may be bonded to a linker protein on a liposome by use of a divalent reagent such as bissulfosuccinimidylsuberate, disuccinimidylglutarate, dithiobissuccinimidylpropionate, disuccinimidylsuberate, 3,3′-dithiobissulfosuccinimidylpropionate, ethylene glycol bissuccinimidylsuccinate, or ethylene glycol bissulfosuccinimidylsuccinate.
To describe this more specifically, one of the ends of a divalent crosslinking reagent is bonded to all amino groups of a linker protein. Then, the reduced terminals of sugar chains are glycosylaminated to prepare a sugar chain glycosylamine compound. The amino groups of the sugar chains are bonded to the other unreacted terminals of part of the divalent crosslinking reagent bonded onto the liposome.
The covalent bond formed between a sugar chain and/or a hydrophilic compound and a liposome, or the covalent bond formed between a sugar chain and/or a hydrophilic compound and a linker protein can be cleaved when the liposome is taken in a cell. More specifically, when a linker protein and a sugar chain are covalently bonded via a disulfide bond, the disulfide bond is intracellularly reduced to cleave the sugar chain. When the sugar chain is cleaved, the surface of the liposome becomes hydrophobic. As a result, the liposome bonds to the biomembrane, causing disturbance of the membrane stability, and releases a medicinal drug contained therein.
Subsequently, using the unreacted terminals (constituting major part) of the divalent reagent remaining intact on the surface of the protein on the sugar-chain bonded liposome membrane, hydrophilization treatment is performed. More specifically, the unreacted terminals of the divalent reagent bonded to the protein on the liposome are reactively bonded with a hydrophilic compound such as tris(hydroxymethyl)aminomethane, thereby hydrophilizing the entire surface of the liposome.
The hydrophilization of the surface of a liposome and a linker protein improves delivery of the liposome to various types of tissues and blood retention and delivery of the liposome to various types of tissues for the reasons below. It is conceivable that the hydrophilization of the surfaces of the liposome and the linker protein causes tissues to recognize the portion except for the sugar chain as an in-vivo moisture content, with the result that other tissues except for a target tissue fail to recognize the liposome and only the sugar chain is recognized by a lectin (sugar chain recognition protein) of the target tissue.
Subsequently, the sugar chain is bonded to a linker protein on the liposome. This is performed by glycosylaminating the reduced terminal of a saccharide constituting the sugar chain by an ammonium salt such as NH4HCO3 or NH2COONH4, and then, bonding the linker protein bonded onto liposome membrane to the saccharide glycosylaminated in the above by use of a divalent reagent such as bissulfosuccinimidylsuberate, disuccinimidylglutarate, dithiobissuccinimidylpropionate, disuccinimidylsuberate, 3,3′-dithiobissulfosuccinimidylpropionate, ethylene glycol bissuccinimidylsuccinate, or ethylene glycol bissulfosuccinimidylsuccinate. As a result, the liposomes shown in FIGS. 22 to 33, 44 to 47, 1 to 6 can be obtained. These sugar chains are commercially available.
The particle size of the liposome of the present invention and the liposome having a sugar chain, etc., bonded thereto falls within the range of 30 to 500 nm, and preferably 50 to 350 nm. The liposome of the present invention is desirably charged negatively. The liposome, if negatively charged, can prevent interaction with other negatively charged cells in vivo. The zeta potential of the surface of the liposome of the present invention is −50 to 10 mV, preferably −40 to 0 mV, and more preferably −30 to −10 mV at 37° C. as measured in a physiological saline.
When a sugar chain is bonded, the binding density of the sugar chain falls within the range 1 to 60 chains per molecule of a linker protein, preferably 1 to 40, and further preferably 1 to 20. When a linker protein is used, the binding density falls within the range of 1 to 30000 per liposome particle, preferably 1 to 20000, and further preferably, 1 to 10000; 100 to 30000, preferably 100 to 20000, and further preferably 100 to 10000; or 500 to 30000, preferably 500 to 20000, and further preferably 500 to 10000. When no linker protein is used, the number of sugar chains that may be bonded is 1 to 500000 per liposome particle, preferably 1 to 300000, and further preferably, 1 to 100000 or more, in maximum.
In the present invention, the targetability to a target cell and tissue can be controlled by selecting the structure and amount of sugar chain to be bonded in various manners.
The controlled intestinal absorption can be increased by selecting the type and amount of sugar chain to be bonded. More specifically, by binding not only a sugar chain increasing the controlled intestinal absorption but also a sugar chain capable of targeting to a predetermined tissue or organ to a liposome, a liposome having two characteristics: targetability to a predetermined tissue or organ and controlled intestinal absorption can be prepared.
As described above, the lectin to which the targeting liposome of the present invention is specifically bonded is determined based on the type and amount of sugar chain to be bonded. In this mechanism, the liposome of the present invention reaches the predetermined tissue or organ. Alternatively, by selecting the structure and amount of sugar chain to be bonded, the liposome can be delivered to a lesion site such as a cancer tissue.
In the present invention, the targetability of a liposome to a target cell and tissue can be controlled by selecting the structure and amount of the sugar chain to be bonded. Depending upon a sugar chain, the liposome of the present invention is directed to tissues or organs such as blood, liver, spleen, lung, brain, small intestinal tract, heart, thymus gland, kidney, pancreas, muscle, large intestinal tract, bone, bone marrow, cancer tissue, inflammatory tissue and lymph node. For example, as shown in
The liposomes shown in FIGS. 44 to 47 of the invention generally show extremely high intestinal absorption. When the density of a sugar chain bonded to each of the liposomes is controlled, the intestinal absorption can be controlled and a medicinal drug can be more efficiently delivered to a target site, and a side effect of the medicinal drug can be reduced. For example, FIGS. 48 to 51 (showing Examples) show the deliver rate (intestinal absorption) of the liposome from the intestinal tract into blood in the cases where the amount of sugar chain bonded to each of 4 types of sugar chain modified liposomes is varied in three levels.
Note that the amount of sugar chain to be bonded to a linker protein bonded liposome is changed by bonding the sugar chains of three levels (1) 50 μg, 2) 200 μg and 3) 1 mg). According to the results of Examples, in the cases of sugar chains of 6′ sialyllactose trisaccharide and 6′-sialyllactosamine, as the sugar-chain density increases, the intestinal absorption gradually decreases. Conversely, in the cases of sugar chains of 3′-sialyllactose trisaccharide and 3′-sialyllactosamine, the intestinal absorption increases. These facts demonstrate that the intestinal absorption varies depending upon the amount of sugar chain bonded onto a liposome for each type of sugar chain. Therefore, the intestinal absorption can be controlled by appropriately setting the amount of sugar chain bonded onto a liposome for each type of sugar chain.
When a compound having a medicinal effect is encapsulated in a liposome according to the present invention, the liposome is delivered to a predetermined tissue or organ, taken into the cells of the tissue and organ, releases the compound having a medicinal effect and exert the medical effect. In the case of a liposome having a sugar chain bonded thereto, the liposome reaches a predetermined tissue or organ depending upon the targetability of the sugar chain. Furthermore, even in the case of a liposome having no sugar chain bonded thereto, the liposome can reach a predetermined tissue and organ, since the liposome is stable in vivo, and therefore, the half-life of the liposome in-vivo is long.
The compound having a medicinal effect is not particularly limited and a wide variety of known proteins and pharmaceutical compounds can be used. When a medicinal compound for treating a predetermined disease such as an anticancer drug is contained in the liposome of the present invention, the liposome can be used as a therapeutic drug for the predetermined disease. As a compound having a medicinal effect to be encapsulated in the liposome of the present invention, mention may be made of gene therapeutic drugs such as DNA, RNA, and siRNA.
Examples of medicinal compounds to be encapsulated in the liposome of the present invention include medicinal drugs for tumors such as an anticancer based on an alkylating compound, metabolic antagonist, plant derived anticancer drug, anticancer antibiotic, BRM, cytokine, anticancer drug based on a platinum complex, immunotherapeutic drug, hormonal anticancer drug, and monoclonal antibody; medicinal drugs for the central nerve; medicinal drugs for the peripheral nervous system/sensory organ; therapeutic drugs for a respiratory disease; medicinal drugs for a circulatory organ; medicinal drugs for a digestive organ; hormonal medicinal drugs; medicinal drugs for a urinary/genital organ; medicinal drugs for external application; vitamins/analeptics; medicinal drugs for blood and body fluid; metabolic medicine; antibiotic/chemotherapeutic agents; medicinal drugs for medical check; anti-inflammatory agents; medicinal drugs for eye disorder; medicinal drugs for the central nervous system; medicinal drugs for the autoimmune system; medicinal drugs for the circulatory organ; medicinal drugs for lifestyle-related diseases such as diabetes and hyperlipemia; various oral, pulmonarg, transdermal or transmucosal drugs; adenocortical hormones; immunosuppressive agents; antibiotics; anti-viral agents; neovascularization inhibitors; cytokines; chemokines; anti-cytokine antibodies; anti-chemokine antibodies; anti-cytokine/chemokine receptor antibodies; nucleic acid preparations involved in gene therapy such as siRNA, mRNA, smRNA, antisense ODN and DNA; neuroprotective factors; and various antibody medicines.
Examples of the medicinal drugs for tumors include alkylating agent such as nitrogen mustard-N-oxide hydrochloride, cyclofosfamide, ifosfamide, brusfan, nimustine hydrochloride, mitobronitol, melphalan, dacarbazine, ranimustine, and estramustine sodium phosphate, metabolic antagonists such as mercaptopurine, thioinosine (mercaptopurineriboside), methotrexate, enocitabine, cytarabine, ancitabine hydrochloride (cyclocytidine hydrochloride), fluorouracil, 5-FU, tegafur, doxifluridine, and carmofur; plant-derived anticancer drugs such as alkaloids including etoposide, vinblastine sulfate, vincristine sulfate, vindesine sulfate, paclitaxel, taxol, irinotecan hydrochloride, and nogitecan hydrochloride; anticancer antibiotics such as actinomycin D, mitomycin C, chromomycin A3, bleomycin hydrochloride, bleomycin sulfate, peplomycin sulfate, daunorubicin hydrochloride, doxorubicin hydrochloride, aclarubicin hydrochloride (acrasinomycin A), pirarubicin hydrochloride, epirubicin hydrochloride, and neocarcinostatin, and others including mitoxantrone hydrochloride, carboplatin, cisplatin, L-asparaginase, aceglatone, procarbazine hydrochloride, tamoxifen citrate, ubenimex, lenthinan, sizofiran, medroxyprogesterone acetate, fosfestrol, mepitiostane, and epitiostanol. The present invention may include derivatives of the aforementioned medicinal drugs.
The liposome of the present invention containing a medicinal drug as mentioned above can be used in therapy for diseases such as cancer and inflammation. The term “cancer” used herein includes all types of neoplastic diseases such as tumors and leukemia. When a sugar chain modified liposome according to the present invention containing such a medicinal drug is administered, the medicinal drug is accumulated on the carcinogenic and inflammatory sites, compared to the case where the medicinal drug is solely administered. More specifically, it is accumulated twice, preferably 5 times or more, further preferably 10 times or more and particularly preferably 50 times or more as large as the amount of single administration.
Note that a compound having a medicinal effect may be encapsulated in a liposome or bonded onto the surface of the liposome. For example, a protein may be bonded to the surface of the liposome in the same manner as in binding a linker protein. Other compounds may be bonded by a known method with the help of a functional group contained therein. Such a compound is encapsulated in a liposome by the method below. More specifically, a medicinal drug may be encapsulated in a liposome by a known method, and for example, a liposome is formed using a solution containing a medicinal drug or the like and a lipid such as a phosphatidylcholine, phosphatidylethanolamine, phosphatidic acid, long-chain alkyl phosphate, ganglioside, glycolipid, or phosphatidylglycerols, and cholesterol, thereby encapsulating the medicinal drug or the like in the liposome.
Therefore, the liposome preparation of the present invention obtained by encapsulating a medicinal drug or a gene that may be subjected to therapy or diagnosis therein is selectively controlled so as to be delivered to a cancer tissue, inflammatory tissue or other tissues. Thus, it is possible to apply the medicinal drug or diagnostic drug intensively to a target cell or tissue, thereby increasing the efficacy of the drug. On the other hand, it is possible to reduce the amount of the drug taken into other cells or tissues, thereby mitigating a side effect.
The liposome or sugar chain modified liposome of the present invention may be administered as a pharmaceutical composition in various forms. Examples of such administration forms include instillation by an eyedrop; peroral administration by a tablet, capsule, granule, powder, and syrup; and parenteral administration by injection, drip infusion, and suppository. These compositions are produced by known methods and contain carriers, diluents and excipients generally used in the field of medicinal preparation. As carriers and excipients for tablets, use may be made of gelation agents, lactose, and magnesium stearate. Injection agents are prepared by dissolving, suspending or emulsifying the sugar chain bonded liposomes of the present invention in an aseptic aqueous or oily solution that is generally used in an injection agent. As the aqueous solution for injection, use may be made of physiological saline and isotonic solutions containing glucose and other auxiliary agents. In this case, an appropriate dissolution auxiliary agent(s), such as an alcohol, polyalcohol e.g., propylene glycol, and nonionic surfactant may be used simultaneously. As the oily solution, use may be made of sesame oil and soybean oil. As the dissolution auxiliary agent, use may be simultaneously made of benzyl benzoate and benzyl alcohol.
The administration route of a pharmaceutical composition of the present invention is not limited and includes instillation, peroral administration, intravenous injection and intramuscular injection. The administration amount can be appropriately determined depending upon significance of the disease. In the present invention, a pharmaceutically effective amount of composition is administered to a patient. The phrase “a pharmaceutically effective amount is administered” refers to administering a medicinal drug in an appropriate amount for treating a disease. The administration number of times of a pharmaceutical composition of the present invention is appropriately selected depending upon the symptom of a patient.
The liposome having a sugar chain on the surface is suitable for parenteral administration (intravenous injection) and peroral administration. The administration amount may be from one in tens to one in thousands relative to a conventional non-targeting liposome preparation. More specifically, the amount of medicinal drug to be contained in a liposome may be 0.0001 to 1000 mg, preferably 0.0001 to 10 mg, and further preferably, 0.0001 to 0.1 mg per body weight (kg). The liposome of the present invention includes a liposome not containing a targeting sugar chain but binding a hydrophilic compound thereto. Since such a liposome is hydrophilized, it has excellent in-vivo stability and a long half-life. Therefore, the liposome produces a sufficient effect in a low content.
When the pharmaceutical composition of the present invention is used for diagnosis, a labeling compound such as a fluorescent pigment, or radioactive compound is bonded to liposomes. When the liposomes tagged with a labeling compound are bonded to a lesion, the labeling compound is taken in lesion cells. Therefore, a disease can be detected and diagnosed based on the presence of the targeting compound as an index.
Furthermore, the liposome of the present invention having a cosmetic or a fragrance encapsulated therein or bonded thereto may be used as a cosmetic composition. The term “cosmetic” refers to a product “which is generally used by applying and rubbing, dispersing it or by analogous manner, in order to make a human body clean, beautiful, and more attractive, change facial appearance, and maintain the skin or hair healthy and which acts mildly to a human body”. In the present invention, the term “cosmetic” includes not only general cosmetics but also quasi drugs defined as a product acting mildly, not used in therapy or prophylaxis of a disease, and not directed to having an effect on the structure and function of a body. Such a cosmetic may include those acting on cells such as the skin cells and activating the cells.
Examples of the cosmetics include those applied to the skin, hair, head hair, and head skin.
More specifically, a cosmetic may contain a skin whitener (whitening agent) such as magnesium phosphate-ascrobate, kojic acid, placenta extract, arbutin, and ellagic acid; vitamins such as vitamin A, vitamin B, vitamin C and vitamin E; hormones such as estrogen, estradiol, estrone, ethinylestradiol, cortisone, hydrocortisone, prednisone; skin tonic agents such as citric acid, tartaric acid, lactic acid, aluminium chloride, aluminium sulfate, potassium sulfate, alum, aluminium chlorohydroxyl allantorin, aluminium dihydroxy allantoin, zinc paraphenol sulfonate, zinc sulfate; hair-growth accelerating agents such as cantharis tincture, capsaicin tincture, ginger tincture, swertiae herba extract, garlic extract, hinokitiol, carpronium chloride, and pentadecanoic acid glyceride; others such as elastin, collagen, chamomile extract, glycyrrhiza extract, β-glycyrrhetic acid, glycyrrhizinic acid, γ-orizanol, calcium pantothenate, pantothenyl ethyl ether, and amino acids. Other than these, the cosmetic may contain compounds capable of activating cells physiologically active proteins such as interferons, interleukins, lysozyme, lactoferrin, and transferrin.
Besides these, use may be made of cosmetics described in #New Cosmetic Science”, 2nd ed. Edited by Takeo Mitsui, published by Nanzando, Jan. 18, 2002; and “Fragrance Science”—Theory and Reality—, 4th ed., written by Takeo Tamura, Hiroshi, Hirota, published by Fragrance Journal, Jun. 30, 2001.
The composition containing a liposome according to the present invention having a cosmetic encapsulated therein or bonded thereto stays on the surface of the skin, where the cosmetic contained in the liposome is released and produces an effect on the skin surface. Alternatively, the liposome by itself is transdermally absorbed. When the liposome reaches the stratum corneum or the tissue under the stratum corneum, it is absorbed into the cells of the tissue, releases the cosmetic, which produces a medicinal effect.
A sugar chain may not be bonded to the liposome that is used in a cosmetic composition. In this case, the liposome stays on the skin or the underneath the skin and releases a cosmetic. Alternatively, a sugar chain may be bonded to the liposome so as to be accumulated specifically onto a target of an inflammatory site of the skin.
The cosmetic composition of the present invention may contain an aqueous composition and an oily composition usually contained as cosmetics in addition to the liposome described above. Examples of the aqueous composition include a moisturizing agent, thickening agent, and alcohol. Examples of the moisturizing agent include glycerin, propylene glycol, and polyhydric alcohol. Examples of the thickening agent include gum tragacanth, pectin, and alginic acid salt. Examples of the alcohol include, ethanol, and isopropanol. Examples of the oily component include olive oil, camellia oil, castor oil, solder, oleic acid, solid paraffin, ceresin, wax, Vaceline, liquid paraffin, silicon oil, synthetic ester oil and synthetic ether.
Furthermore, the liposome of the present invention having a functional food, nutritional supplementary food, or health supplementary food encapsulated therein or bonded thereto may be used as a food composition. The functional food, nutritional food or health supplementary food is not particularly limited and any food may be used as long as it is designed, processed and converted to be efficiently exhibit its function after absorption.
Examples of the functional food, nutritional food or health supplementary food may include ginkgo leaves, echinacea, sawfish coconut palm, St John's Wort. valerian, Black cohosh, milk thistle, evening primrose, grape seed extract, bilberry, feverfew, Japanese angelica root, soybean, French coast pine, garlic, ginseng, tea, ginger, agaricus, Fomes yucatensis, Merto purple, AHCC, yeast β-glucan, Grifola frondosa, propolis, beer yeast, cereals, plum, chlorella, barley young leaves, green juice, vitamins, collagen, Glcosamin, mulberry leaves, Rooibos tea, amino acids, the royal jelly, shiitake mycelia extract, Spirulina, Densichi carrot, cress, plant fermentation food, DHA, EPA, ARA, seaweed, cabbage, aloe, Nikko maple, hop, the extract of oyster, pycnogenol and sesame seeds, etc. These may be directly contained in a liposome and extracts are processed and contained in a liposome. A food composition containing liposomes may be orally taken. The liposomes that are used may not have a sugar chain bonded thereto and may have a sugar chain bonded thereto for enhancing absorption from the intestinal tract or targeting a predetermined tissue or organ. When the liposome of the present invention is administered as a food composition, it may be processed in the form of liquid beverage, gel food, and solid food. Alternatively, it may be processed in the form of tablets, granules, and the like. The food composition of this invention can be used as a functional food, nutritional or health supplementary food in accordance with types of foods that liposomes contain. For instance, liposome including DHA can be used as an effective functional food, nutritional or health supplementary food for improving a slight senile dementia and amnesia.
Various examples of the present invention will be described below, but the invention is not limited thereto.
Preparation of Liposomes
Liposomes were prepared through an improved type of cholate dialysis based on a previously reported method (Yamazaki, N., Kodama, M. and H.-J. Gabius. Methods Enzymol. 242:56-65 (1994)). More specifically, 46.9 mg of sodium cholate was added to 45.6 mg of lipid mixture consisting of dipalmitoylphosphatidylcholine, cholesterol, dicetylphosphate, ganglioside and dipalmitoylphosphatidylethanolamine at a mole ratio of 35:40:5:15:5, respectively, and the lipid mixture was dissolved in 3 ml of chloroform/methanol solution. The solution was then evaporated, and the resulting deposit was dried in vacuo to obtain a lipid membrane. The obtained lipid membrane was suspended in 3 ml of a TAPS buffer solution (pH 8.4), and was subjected to a supersonic treatment to obtain a clear micelle suspension. Then, this micelle suspension was subjected to ultrafiltration by using a PM 10 membrane (Amicon Co., USA) and a PBS buffer solution (pH 7.2) to prepare 10 ml of a uniform liposome (average size of 100 nm).
Hydrophilization of Lipid Membrane Surface of Liposomes
10 ml of the liposome solution prepared in Example 1 was subjected to ultrafiltration by using an XM 300 membrane (Amicon Co., USA) and a CBS buffer solution (pH 8.5) to adjust the pH of the solution to 8.5. Then, 10 mg of bis(sulfosuccinimidyl) suberate (BS3; Pierce Co., USA) crosslinking reagent was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night to complete the reaction between the BS3 and the dipalmitoylphosphatidyletanolamine of the lipid on the liposome membrane. This liposome solution was then subjected to ultrafiltration by using an XM 300 membrane and a CBS buffer solution (pH 8.5). Then, 40 mg of tris(hydroxymethyl)aminomethane dissolved in 1 ml of CMS buffer solution (pH 8.5) was added to 10 ml of the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and stirred at 7° C. for one night to complete the reaction between the BS3 bonded to the lipid on the liposome membrane and the tris(hydroxymethyl)aminomethane. In this manner, the hydroxyl groups of the tris(hydroxymethyl)aminomethane were coordinated on the dipalmitoylphosphatidyletanolamine of the lipid on the liposome membrane to achieve the hydrophilization of the lipid membrane surface of the liposome.
Bonding of Human Serum Albumin (HSA) to Membrane Surface of Liposomes
Human serum albumin (HSA) was bonded to the membrane surface of the liposome through a coupling reaction method based on a previously reported method (Yamazaki, N., Kodama, M. and H.-J. Gabius. Methods Enzymol. 242:56-65 (1994)). More specifically, the reaction was carried out through a two-stage reaction method. That is, 43 mg of sodium metaperiodate dissolved in 1 ml of TAPS buffer solution (pH 8.4) was added to 10 ml of the liposome obtained in Example 2, and the obtained solution was stirred at room temperature for 2 hours to periodate-oxidize the ganglioside on the membrane surface of the liposome. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 8.0) to obtain 10 ml of oxidized liposome. 20 mg of human serum albumin (HSA) was then added to the liposome solution, and the obtained solution was stirred at 25° C. for 2 hours. Then, 100 μl of 2M NaBH3CN was added to the PBS buffer solution (pH 8.0), and the obtained solution was stirred at 110° C. for one night to bond the HSA to the liposome membrane surface through a coupling reaction between the HSA and the ganglioside on the liposome. Then, 10 ml of HSA-bonded liposome solution was obtained through an ultrafiltration using an XM 300 membrane and a CBS buffer solution (pH 8.5).
Bonding of Lactose Disaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces
50 μg, 200 μg, or 1 mg of lactose disaccharide (Wako Pure Chemical Co., Japan) was added to 0.5 ml of water solution having 0.25 g of NH4HCO3 dissolved therein, and the obtained solution was stirred at 37° C. for 3 days. Then, the solution was filtered by using a filter of 0.45 μm to complete an amination reaction at the reduction terminal of the sugar chain and obtain 50 μg of glycosylamine compound of the lactose disaccharide. Then, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl propionate) (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in Example 3. The obtained solution was then stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome in which the DTSSP was bonded to the HSA on the liposome. Then, 50 μg of the glycosylamine compound of the lactose disaccharide was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 7.2) to bond the lactose disaccharide to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this manner, 3 types of liposomes (2 ml each), differing in the amount of sugar chain bonded thereto (referred to as LAC-1 (50 μg), LAC-2 (200 μg), and LAC-3 (1 mg)), in which lactose disaccharide is bonded to the liposome through human serum albumin (
Bonding of 2′-Fucosyllactose Trisaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces
50 μg, 200 μg, or 1 mg of 2′-fucosyllactose trisaccharide (Wako Pure Chemical Co., Japan) was added to 0.5 ml of water solution having 0.25 g of NH4HCO3 dissolved therein, and the obtained solution was stirred at 37° C. for 3 days. The solution was then filtered by using a filter of 0.45 μm to complete an amination reaction at the reduction terminal of the sugar chain and obtain 50 μg of glycosylamine compound of the 2′-fucosyllactose trisaccharide. Then, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl propionate) (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in Example 3. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome in which the DTSSP was bonded to the HSA on the liposome. Then, 50 μg of the glycosylamine compound of the 2′-fucosyllactose trisaccharide was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 7.2) to bond the 2′-fucosyllactose trisaccharide to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this manner, 3 types of liposomes (2 ml each), differing in the amount of sugar chain bonded thereto (referred to as 2FL-1 (50 μg), 2FL-2 (200 μg), and 2FL-3 (1 mg)), in which 2′-fucosyllactose trisaccharide is bonded to the liposome through human serum albumin (
Bonding of Difucosyllactose Tetrasaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces
50 μg, 200 μg, or 1 mg of difucosyllactose tetrasaccharide (Wako Pure Chemical Co., Japan) was added to 0.5 ml of water solution having 0.25 g of NH4HCO3 dissolved therein, and the obtained solution was stirred at 37° C. for 3 days. The solution was then filtered by using a filter of 0.45 μm to complete an amination reaction at the reduction terminal of the sugar chain to obtain 50 μg of glycosylamine compound of the difucosyllactose tetrasaccharide. Then, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl propionate) (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in Example 3. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome in which the DTSSP was bonded to the HSA on the liposome. Then, 50 μg of the glycosylamine compound of the difucosyllactose tetrasaccharide was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 7.2) to bond the difucosyllactose tetrasaccharide to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this manner, 3 types of liposomes (2 ml each), differing in the amount of sugar chain bonded thereto (referred to as DFL-1 (50 μg), DFL-2 (200 μg), and DFL-3 (1 mg)), in which difucosyllactose tetrasaccharide is bonded to the liposome through human serum albumin (
Bonding of 3-Fucosyllactose Trisaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces
50 μg, 200 μg, or 1 mg of 3-fucosyllactose trisaccharide (Wako Pure Chemical Co., Japan) was added to 0.5 ml of water solution having 0.25 g of NH4HCO3 dissolved therein, and the obtained solution was stirred at 37° C. for 3 days. The solution was then filtered by using a filter of 0.45 μm to complete an amination reaction at the reduction terminal of the sugar chain to obtain 50 μg of glycosylamine compound of 3-fucosyllactose’ trisaccharide. Then, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl propionate) (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in Example 3. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. The solution was subjected to ultrafiltration by using an XM 300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposomes in which the DTSSP was bonded to the HSA on the liposome. Then, 50 μg of the glycosylamine compound of the 3-fucosyllactose trisaccharide was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. The solution was then subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 7.2) to bond the 3-fucosyllactose trisaccharide to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this manner, 3 types of liposomes (2 ml each), differing in the amount of sugar chain bonded thereto (referred to as 3FL-1 (50 μg), 3FL-2 (200 μg), and 3FL-3 (1 mg)), in which the 3-fucosyllactose trisaccharide is bonded to the liposome through human serum albumin (
Bonding of Lewis X Trisaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces
Liposomes comprising Lewis X Trisaccharide-bonded HSA on the liposome membrane surface were prepared according to the method of Example 4, with the exception that 50 μg of Lewis X trisaccharide (Calbiochem Co., USA) was used in place of the lactose disaccharide. 2 ml of the liposome (LX), in which Lewis X trisaccharide is bonded to the liposome through human serum albumin (
Bonding of Sialyl Lewis X Tetrasaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces
Liposomes comprising sialyl Lewis X tetrasaccaride-bonded HSA on the liposome membrane surface were prepared according to the method of Example 5, with the exception that 50 μg of sialyl Lewis X tetrasaccaride (Calbiochem Co., USA) was used in place of the 2′-fucosyllactose trisaccharide. 2 ml of the liposome (SLX), in which sialyl Lewis X tetrasaccaride is bonded to the liposome through human serum albumin (
Bonding of 3′-Sialyllactosamine Trisaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces
Liposomes comprising 3′-sialyllactosamine trisaccharide-bonded HSA on the liposome membrane surface were prepared according to the method of Example 6, with the exception that 50 μg of 3′-sialyllactosamine trisaccharide (Seikagakukogyou Co., Japan) was used in place of the difucosyllactose tetrasaccharide. 2 ml of the liposome (3SLN), in which 3′-sialyllactosamine trisaccharide is bonded to the liposome through human serum albumin (
Bonding of 6′-Sialyllactosamine Trisaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces
Liposomes comprising 6′-sialyllactosamine trisaccharide-bonded HSA on the liposome membrane surface were prepared according to the method of Example 7, with the exception that 50 μg of 6′-sialyllactosamine trisaccharide (Seikagakukogyou Co., Japan) was used in place of the 3-fucosyllactose trisaccharide. 2 ml of the liposome (6SLN), in which 6′-sialyllactosamine trisaccharide is bonded to the liposome through human serum albumin (
Bonding of Tris(Hydroxymethyl) Aminomethane to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces
For preparing a liposome as a comparative sample, 1 mg of 3,3′-dithiobis (sulfosuccinimidyl propionate) (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in Example 3. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. The solution was then subjected to ultrafiltration by using an XM 300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome in which the DTSSP was bonded to the HSA on the liposome. Then, 13 mg of tris(hydroxymethyl)aminomethane (Wako Co., Japan) was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 7.2) to bond the tris(hydroxymethyl)aminomethane to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this process, an excess amount of tris(hydroxymethyl)aminomethane, that is 13 mg, already exists. Thus, the hydrophilization of the human serum albumin (HSA) bonded on the liposome membrane surface was simultaneously completed. In this manner, 2 ml of the liposome as the comparative sample (TRIS) in which the tris(hydroxymethyl)aminomethane is bonded to human serum albumin (
Hydrophilization of Human Serum Albumin Bonded on Liposome Membrane Surfaces
For the 16 types of sugar-modified liposomes prepared in Examples 4 to 11, the respective HSA protein surfaces were separately hydrophilized through the following process. 13 mg of tris(hydroxymethyl)aminomethane was added to each of the 16 types of sugar-modified liposomes (2 ml each). The respective obtained solutions were stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. The solutions were then subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 7.2) to remove unreacted materials. In this manner, 2 ml of final product for each of the 16 types of hydrophilized sugar-modified liposome complexes (LAC-1, LAC-2, LAC-3, 2FL-1, 2FL-2, 2FL-3, DFL-1, DFL-2, DFL-3, 3FL-1, 3FL-2, 3FL-3, LX, SLX, 3SLN and 6SLN) (total lipid mass: 2 mg, total protein mass: 200 μg, average particle size: 100 nm) were obtained.
Measurement of Lectin-Binding Activity Inhibiting Effect in Each Type of Sugar-Modified Liposome Complex
The in vitro lectin-binding activity of each of the 16 types of hydrophilized sugar-modified liposomes prepared in Example 13 was measured through an inhibition test using a lectin-immobilized microplate by methods known in the art (see, e.g., Yamazaki, N., et al., Drug Delivery System, 14:498-505 (1999)). More specifically, a lectin (E-selectin; R&D Systems Co., USA) was immobilized on a 96 well-microplate. Then, 0.1 μg of biotinylated and fucosylated fetuin as a comparative ligand, and various types of sugar-modified liposome complexes having different densities (each including 0.01 μg, 0.04 μg, 0.11 μg, 0.33 μg or 1 μg of protein), were placed on the lectin-immobilized plate, and incubated at 4° C. for 2 hours. After washing with PBS (pH 7.2) three times, horseradish peroxidase (HRPO)-conjugated streptavidin was added to each of the wells. The respective test solutions were incubated at 4° C. for 1 hour, and then washed with PBS (pH 7.2) three times. Then, peroxidase substrates were added to the test solutions, and incubated at room temperature. Then, the absorbance at 405 nm of each of the test solutions was determined by a microplate reader (Molecular Devices Corp., USA). For the biotinylation of the fucosylated fetuin, each of the test solutions was subject to a sulfo-NHS-biotin reagent (Pierce Chemical Co., USA) treatment and refined by using a Centricon-30 (Amicon Co., USA). HRPO-conjugated streptavidin was prepared by oxidizing HRPO and bonding streptavidin to the oxidized HRPO through a reductive amination method using NaBH3CN. This measurement result is shown in Table 1. 1
125I-Labeling of Each Type of Sugar-Modified Liposome Through the Chloramine T Method
A chloramine T (Wako Pure Chemical Co., Japan) solution and a sodium disulfite solution were prepared at 3 mg/ml and 5 mg/ml, respectively. 50 μl of the 16 different types of hydrophilized sugar-modified liposomes prepared in Example 13, and the liposome of Example 12, were put into separate Eppendorf tubes. Then, 15 μl of 125I-NaI (NEN Life Science Product, Inc. USA) and 10 μl of chloramine T solution were added thereto and reacted therewith. 10 μl of chloramine T solution was added to the respective solutions every 5 minutes. After 15 minutes from the completion of the above procedure repeated twice, 100 μl of sodium disulfite serving as a reducer was added to the solutions to stop the reaction. Then, each of the resulting solutions was placed on a Sephadex G-50 (Phramacia Biotech. Sweden) column chromatography, and eluted by PBS to purify a labeled compound. Finally, a non-labeled liposome complex was added to each of the solutions to adjust a specific activity (4×106 Bq/mg protein). In this manner, 16 types of 125I-labeled liposome solutions were obtained.
Measurement of Transfer Rate of Each Type of Sugar-Modified Liposome Complex to Tissues of Mice with Cancer
Using an oral sonde, 13 of the different types of 125I-labeled, hydrophilized sugar-modified liposomes of Example 15 (LAC-1, LAC-2, LAC-3, 2FL-1, 2FL-2, 2FL-3, DFL-1, DFL-2, DFL-3, 3FL-1, 3FL-2, 3FL-3 and TRIS) (equivalent to 3 μg of protein per mouse) were administered to male ddY mice (7 weeks of age) which had abstained from food, except for water, for one whole day, in an amount of 0.2 ml which is equivalent to 3 μg of protein per mouse. After 10 minutes, 1 ml of blood was taken from descending aorta under Nembutal anesthesia. Then, 125I-radioactivity in the blood was measured with a gamma counter (Aloka ARC 300). Further, in order to check the in vivo stability of each type of liposome complex, serum from each mouse's blood was subjected to chromatography using a Sephadex G-50. As a result, most of the radioactivity in each sample of serum was found in void fractions having a high molecular weight, and it was proved that each type of liposome complexes has a high in vivo stability. The radioactivity transfer rate from intestine to blood was represented by the ratio of the radioactivity per ml of blood to the total of given radioactivity (% dose/ml blood). This measurement result is shown in FIGS. 10 to 13.
Measurement of Distribution Rate of Each Type of Sugar-Modified Liposome Complex to Tissues of Mice with Cancer
Ehrlich ascites tumor (EAT) cells (about 2×107 cells) were implanted subcutaneously into the femoral region in male ddY mice (7 weeks of age), and the mice were used in this test after the tumor tissues grew to 0.3 to 0.6 g (after 6 to 8 days). Five of the different types of 125I-labeled, hydrophilized sugar-modified liposome complexes (LX, SLX, 3SLN, 6SLN and TRIS) of Example 15 were injected into the tail veins of the mice in an amount of 0.2 ml which is equivalent to 3 μg of protein per mouse. After 60 minutes, tissues (blood, liver, spleen, lung, brain, inflammatory tissues around cancer, cancer and lymph node) were extracted, and the radioactivity of each of the extracted tissues was measured with a gamma counter (Aloka ARC 300). The distribution rate of the radioactivity in each of the tissues was represented by a ratio of the radioactivity per gram of each of the tissues to the total of given radioactivity (% dose/g tissue). This measurement result is shown in FIGS. 14 to 21.
The results from these experiments show that the sugar-modified liposomes of the present invention are innovative in that they are excellent in intestinal absorption and are capable of being administered via the intestine, which has not been found in conventional liposome related products. In addition, the intestinal absorption can be controlled by adjusting the identity and amount of the sugar chain bonded to the liposomes.
Furthermore, the in vivo mobility of sugar-modified liposomes of the present invention, and their ability to target selected tissues in vivo, can be facilitated or suppressed in a living body by utilizing the difference in the molecular structure of the sugar chain, and varying their amounts.
Thus, the sugar-modified liposomes of the present invention can be used to deliver drugs or genes through the intestine efficiently and safely without any side effects. They may also be used as an effective delivery mechanism for selectively delivering drugs or genes to target tissues such as blood, liver, spleen, lung, brain, cancer tissues, inflammatory tissue, or lymph node, and can be used in DDS materials in light of their enhanced mobility. Thus, the liposomes of the present invention are useful particularly in the medical and pharmaceutical fields.
Bonding of α-1,2-Mannobiose Disaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces
50 μg of α-1,2-mannobiose disaccharide (Calbiochem Co., USA) was added to 0.5 ml of water solution having 0.25 g of NH4HCO3 dissolved therein, and the obtained solution was stirred at 37° C. for 3 days. Then, the solution was filtered by using a filter of 0.45 μm to complete an amination reaction at the reduction terminal of the sugar chain and obtain 50 μg of glycosylamine compound of the α-1,2-mannobiose disaccharide. Then, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl propionate) (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in Example 3. The obtained solution was then stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome in which the DTSSP was bonded to the HSA on the liposome. Then, 50 μg of the glycosylamine compound of the α-1,2-mannobiose disaccharide was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 7.2) to bond the α-1,2-mannobiose disaccharide to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this manner, 2 ml of a liposome (referred to as A2), in which α-1,2-mannobiose disaccharide is bonded to the liposome through human serum albumin (
Bonding of α-1,3-Mannobiose Disaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces
50 μg of α-1,3-mannobiose disaccharide (Calbiochem Co., USA) was added to 0.5 ml of water solution having 0.25 g of NH4HCO3 dissolved therein, and the obtained solution was stirred at 37° C. for 3 days. Then, the solution was filtered by using a filter of 0.45 μm to complete an amination reaction at the reduction terminal of the sugar chain and obtain 50 μg of glycosylamine compound of the α-1,3-mannobiose disaccharide. Then, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl propionate) (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in Example 3. The obtained solution was then stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome in which the DTSSP was bonded to the HSA on the liposome. Then, 50 μg of the glycosylamine compound of the α-1,3-mannobiose disaccharide was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 7.2) to bond the α-1,3-mannobiose disaccharide to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this manner, 2 ml of a liposome (referred to as A3), in which α-1,3-mannobiose disaccharide is bonded to the liposome through human serum albumin (
Bonding of α-1,4-Mannobiose Disaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces
50 μl of α-1,4-mannobiose disaccharide (Calbiochem Co., USA) was added to 0.5 ml of water solution having 0.25 g of NH4HCO3 dissolved therein, and the obtained solution was stirred at 37° C. for 3 days. Then, the solution was filtered by using a filter of 0.45 μm to complete an amination reaction at the reduction terminal of the sugar chain and obtain 50 μg of glycosylamine compound of the α-1,4-mannobiose disaccharide. Then, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl propionate) (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in Example 3. The obtained solution was then stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome in which the DTSSP was bonded to the HSA on the liposome. Then, 50 μg of the glycosylamine compound of the alpha-1,4-mannobiose disaccharide was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 7.2) to bond the α-1,4-mannobiose disaccharide to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this manner, 2 ml of a liposome (referred to as A4), in which α-1,4-mannobiose disaccharide is bonded to the liposome through human serum albumin (
Bonding of α-1,6-Mannobiose Disaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces
50 μg of α-1,6-mannobiose disaccharide (Calbiochem Co., USA) was added to 0.5 ml of water solution having 0.25 g of NH4HCO3 dissolved therein, and the obtained solution was stirred at 37° C. for 3 days. Then, the solution was filtered by using a filter of 0.45 μm to complete an amination reaction at the reduction terminal of the sugar chain and obtain 50 μg of glycosylamine compound of the α-1,6-mannobiose disaccharide. Then, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl propionate) (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in Example 3. The obtained solution was then stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome in which the DTSSP was bonded to the HSA on the liposome. Then, 50 μg of the glycosylamine compound of the α-1,6-mannobiose disaccharide was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 7.2) to bond the α-1,6-mannobiose disaccharide to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this manner, 2 ml of a liposome (referred to as A6), in which α-1,6-mannobiose disaccharide is bonded to the liposome through human serum albumin (
Bonding of α-1,3-α-1,6-Mannotriose Trisaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces
50 μg of α-1,3-α-1,6-mannotriose trisaccharide (Calbiochem Co., USA) was added to 0.5 ml of water solution having 0.25 g of NH4HCO3 dissolved therein, and the obtained solution was stirred at 37° C. for 3 days. Then, the solution was filtered by using a filter of 0.45 μm to complete an amination reaction at the reduction terminal of the sugar chain and obtain 50 μg of glycosylamine compound of the α-1,3-α-1,6-mannotriose trisaccharide. Then, 1 mg of 3,3′-dithiobis (sulfosuccinimidyl propionate) (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in Example 3. The obtained solution was then stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome in which the DTSSP was bonded to the HSA on the liposome. Then, 50 μg of the glycosylamine compound of the α-1,3-α-1,6-mannotriose trisaccharide was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 7.2) to bond the α-1,3-α-1,6-mannotriose trisaccharide to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this manner, 2 ml of a liposome (referred to as A36), in which α-1,3-α-1,6-mannotriose trisaccharide is bonded to the liposome through human serum albumin (
Bonding of Oligomannose-3 Pentasaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces
50 μg of oligomannose-3 pentasaccharide (Calbiochem Co., USA) was added to 0.5 ml of water solution having 0.25 g of NH4HCO3 dissolved therein, and the obtained solution was stirred at 37° C. for 3 days. Then, the solution was filtered by using a filter of 0.45 μm to complete an amination reaction at the reduction terminal of the sugar chain and obtain 50 μg of glycosylamine compound of the oligomannose-3 pentasaccharide. Then, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl propionate) (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in Example 3. The obtained solution was then stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome in which the DTSSP was bonded to the HSA on the liposome. Then, 50 μg of the glycosylamine compound of the oligomannose-3 pentasaccharide was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 7.2) to bond the oligomannose-3 pentasaccharide to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this manner, 2 ml of a liposome (referred to as Man3), in which oligomannose-3 pentasaccharide is bonded to the liposome through human serum albumin (
Bonding of Oligomannose-4b Hexasaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces
50 μg of oligomannose-4b hexasaccharide (Calbiochem Co., USA) was added to 0.5 ml of water solution having 0.25 g of NH4HCO3 dissolved therein, and the obtained solution was stirred at 37° C. for 3 days. Then, the solution was filtered by using a filter of 0.45 μm to complete an amination reaction at the reduction terminal of the sugar chain and obtain 50 μg of glycosylamine compound of the oligomannose-4b hexasaccharide. Then, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl propionate) (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in Example 3. The obtained solution was then stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome in which the DTSSP was bonded to the HSA on the liposome. Then, 50 μg of the glycosylamine compound of the oligomannose-4b hexasaccharide was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 7.2) to bond the oligomannose-4b hexasaccharide to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this manner, 2 ml of a liposome (referred to as Man 4b), in which oligomannose-4b hexasaccharide is bonded to the liposome through human serum albumin (
Bonding of Oligomannose-5 Heptasaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces
50 μg of oligomannose-5 heptasaccharide (Calbiochem Co., USA) was added to 0.5 ml of water solution having 0.25 g of NH4HCO3 dissolved therein, and the obtained solution was stirred at 37° C. for 3 days. Then, the solution was filtered by using a filter of 0.45 μm to complete an amination reaction at the reduction terminal of the sugar chain and obtain 50 μg of glycosylamine compound of the oligomannose-5 heptasaccharide. Then, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl propionate) (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in Example 3. The obtained solution was then stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome in which the DTSSP was bonded to the HSA on the liposome. Then, 50 μg of the glycosylamine compound of the oligomannose-5 heptasaccharide was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 7.2) to bond the oligomannose-5 heptasaccharide to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this manner, 2 ml of a liposome (referred to as Man 5), in which oligomannose-5 heptasaccharide is bonded to the liposome through human serum albumin (
Bonding of Oligomannose-6 Octasaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces
50 μg of oligomannose-6 octasaccharide (Calbiochem Co., USA) was added to 0.5 ml of water solution having 0.25 g of NH4HCO3 dissolved therein, and the obtained solution was stirred at 37° C. for 3 days. Then, the solution was filtered by using a filter of 0.45 μm to complete an amination reaction at the reduction terminal of the sugar chain and obtain 50 μg of glycosylamine compound of the oligomannose-6 octasaccharide. Then, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl propionate) (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in Example 3. The obtained solution was then stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome in which the DTSSP was bonded to the HSA on the liposome. Then, 50 μg of the glycosylamine compound of the oligomannose-6 octasaccharide was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 7.2) to bond the oligomannose-6 octasaccharide to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this manner, 2 ml of a liposome (referred to as Man 6), in which oligomannose-6 octasaccharide is bonded to the liposome through human serum albumin (
Bonding of Oligomannose-7 Nonasaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces
50 μg of oligomannose-7 nonasaccharide (Calbiochem Co., USA) was added to 0.5 ml of water solution having 0.25 g of NH4HCO3 dissolved therein, and the obtained solution was stirred at 37° C. for 3 days. Then, the solution was filtered by using a filter of 0.45 μm to complete an amination reaction at the reduction terminal of the sugar chain and obtain 50 μg of glycosylamine compound of the oligomannose-7 nonasaccharide. Then, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl propionate) (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in Example 3. The obtained solution was then stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome in which the DTSSP was bonded to the HSA on the liposome. Then, 50 μg of the glycosylamine compound of the oligomannose-7 nonasaccharide was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 7.2) to bond the oligomannose-7 nonasaccharide to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this manner, 2 ml of a liposome (referred to as Man 7), in which oligomannose-7 nonasaccharide is bonded to the liposome through human serum albumin (
Bonding of Oligomannose-8 Decasaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces
50 μg of oligomannose-8 decasaccharide (Calbiochem Co., USA) was added to 0.5 ml of water solution having 0.25 g of NH4HCO3 dissolved therein, and the obtained solution was stirred at 37° C. for 3 days. Then, the solution was filtered by using a filter of 0.45 μm to complete an amination reaction at the reduction terminal of the sugar chain and obtain 50 μg of glycosylamine compound of the oligomannose-8 decasaccharide. Then, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl propionate) (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in Example 3. The obtained solution was then stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome in which the DTSSP was bonded to the HSA on the liposome. Then, 50 μg of the glycosylamine compound of the oligomannose-8 decasaccharide was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 7.2) to bond the oligomannose-8 decasaccharide to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this manner, 2 ml of a liposome (referred to as Man 8), in which oligomannose-8 decasaccharide is bonded to the liposome through human serum albumin (
Bonding of Oligomannose-9 Undecasaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces
50 μg of oligomannose-9 undecasaccharide (Calbiochem Co., USA) was added to 0.5 ml of water solution having 0.25 g of NH4HCO3 dissolved therein, and the obtained solution was stirred at 37° C. for 3 days. Then, the solution was filtered by using a filter of 0.45 μm to complete an amination reaction at the reduction terminal of the sugar chain and obtain 50 μg of glycosylamine compound of the oligomannose-9 undecasaccharide. Then, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl propionate) (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in Example 3. The obtained solution was then stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome in which the DTSSP was bonded to the HSA on the liposome. Then, 50 μg of the glycosylamine compound of the oligomannose-9 undecasaccharide was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 7.2) to bond the oligomannose-9 undecasaccharide to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this manner, 2 ml of a liposome (referred to as Man 9), in which oligomannose-9 undecasaccharide is bonded to the liposome through human serum albumin (
Hydrophilization of Human Serum Albumin Bonded on Liposome Membrane Surfaces
For the 12 types of sugar-modified liposomes prepared in Examples 18 to 29, the respective HSA protein surfaces were separately hydrophilized through the following process. 13 mg of tris(hydroxymethyl)aminomethane was added to each of the 12 types of sugar-modified liposomes (2 ml each). The respective obtained solutions were stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. The solutions were then subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 7.2) to remove unreacted materials. In this manner, 2 ml of final product for each of the 12 types of hydrophilized sugar-modified liposome complexes (A2, A3, A4, A6, A36, Man3, Man4, Man5, Man6, Man7, Man8 and Man9) were obtained.
Measurement of Lectin-Binding Activity Inhibiting Effect in Each Type of Sugar-Modified Liposome Complex
The in vitro lectin-binding activity of each of the 12 types of hydrophilized sugar-modified liposomes prepared in Examples 18 to 29 and 30 were measured through an inhibition test using a lectin-immobilized microplate by methods known in the art (see, e.g., Yamazaki, N., et al., Drug Delivery System, 14:498-505 (1999)). More specifically, a lectin (E-selectin; R&D Systems Co., USA) was immobilized on a 96 well-microplate. Then, 0.1 μg of biotinylated fetuin as a comparative ligand, and various types of sugar-modified liposome complexes having different densities (each including 0.01 μg, 0.04 μg, 0.11 μg, 0.33 μg or 1 μg of protein), were placed on the lectin-immobilized plate, and incubated at 4° C. for 2 hours. After washing with PBS (pH 7.2) three times, horseradish peroxidase (HRPO)-conjugated streptavidin was added to each of the wells. The respective test solutions were incubated at 4° C. for 1 hour, and then washed with PBS (pH 7.2) three times. Then, peroxidase substrates were added to the test solutions, and incubated at room temperature. Then, the absorbance at 405 nm of each of the test solutions was determined by a microplate reader (Molecular Devices Corp., USA). For the biotinylation of the fucosylated fetuin, each of the test solutions was subject to a sulfo-NHS-biotin reagent (Pierce Chemical Co., USA) treatment and refined by using a Centricon-30 (Amicon Co., USA). HRPO-conjugated streptavidin was prepared by oxidizing HRPO and bonding streptavidin to the oxidized HRPO through a reductive amination method using NaBH3CN. This measurement result is shown in Table 2
[Table 2]
Targeting Liposome
A chloramine T (Wako Pure Chemical Co., Japan) solution and a sodium disulfite solution were prepared at 3 mg/ml and 5 mg/ml, respectively. 50 μl of the 12 different types of sugar-modified liposomes prepared in Examples 18 to 29, and the tris (hydroxymethyl)aminomethane binding liposome, were put into separate Eppendorf tubes. Then, 15 μl of 125I-NaI (NEN Life Science Product, Inc. USA) and 10 μl of chloramine T solution were added thereto and reacted therewith. 10 μl of chloramine T solution was added to the respective solutions every 5 minutes. After 15 minutes from the completion of the above procedure repeated twice, 100 μl of sodium disulfite serving as a reducer was added to the solutions to stop the reaction. Then, each of the resulting solutions was placed on a Sephadex G-50 (Phramacia Biotech. Sweden) column chromatography, and eluted by PBS to purify a labeled compound. Finally, a non-labeled liposome complex was added to each of the solutions to adjust a specific activity (4×106 Bq/mg protein). In this manner, 13 types of 125I-labeled liposome solutions were obtained.
Measurement of Distribution Rate of Each Type of Sugar-Modified Liposome Complex to Tissues of Mice with Cancer
Ehrlich ascites tumor (EAT) cells (about 2×107 cells) were implanted subcutaneously into the femoral region in male ddY mice (7 weeks of age), and the mice were used in this test after the tumor tissues grew to 0.3 to 0.6 g (after 6 to 8 days). Twelve types of the 125I-labeled, hydrophilized sugar-modified liposome complexes of Example 32 were injected into the tail veins of the mice in an amount of 0.2 ml which is equivalent to 3 μg of protein per mouse. After 60 minutes, tissues (blood, liver, spleen, lung, brain, inflammatory tissues around cancer, cancer and lymph node) were extracted, and the radioactivity of each of the extracted tissues was measured with a gamma counter (Aloka ARC 300). The distribution rate of the radioactivity in each of the tissues was represented by a ratio of the radioactivity per gram of each of the tissues to the total of given radioactivity (% dose/g tissue). This measurement result is shown in FIGS. 34 to 43.
Bonding of 3′-Sialyllactose Trisaccharide Chain (Three Kinds with Different Amounts of Bound Sugar Chain) to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces
1) 50 μg, 2) 200 μg or 3) 1 mg of 3′-sialyllactose trisaccharide (Wako Pure Chemical Co., Japan) was added to 0.5 ml water solution having 0.25 g of NH4HCO3, and the obtained solution was stirred at 37° C. for 3 days. Then, the solution was filtered by using a filter of 0.45 μm filter to complete an amination at the reduced terminal of the sugar chain and obtain 50 μg of glycosylamine compound of 3′-sialyllactose 3 saccharide. Then, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl) propionate (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in Example 3. The obtained solution was then stirred at 25° C. for 2 hours and subsequently stirred at 7° C. for one night. Then the solution was subjected to ultrafiltration by using an XM300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome in which DTSPP was bonded to the HSA on the liposome. Then, 50 μg of the glycosylamine compound of 3′-sialyllactose 3 saccharide was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM300 membrane and a PBS buffer solution (ph 7.2) to bond the 3′-sialyllactose trisaccharide to the DTSSP on the human serum albumin bonded on the liposome membrane surface. As the result, three types of liposomes (2 ml each) differing in the amount of sugar chain bonded thereto (referred to as: 1) 3SL-1, 2) 3SL-2 and 3) 3 SL-3), in which 3′-sialyllactose 3 saccharide is bonded to the liposome through human serum albumin (
Bonding of 6′-Sialyllactose Trisaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces (3Types of Liposome Differing in the Amount of Sugar Chain Bonded)
50 μg, 200 μg, or 1 mg of 6′-sialyllactose trisaccharide (Wako Pure Chemical Co., Japan) was added to 0.5 ml of water solution having 0.25 g of NH4HCO3 dissolved therein, and the obtained solution was stirred at 37° C. for 3 days. Then, the solution was filtered by using a filter of 0.45 μm to complete an amination reaction at the reduction terminal of the sugar chain and obtain 50 μg of glycosylamine compound of the 6′-sialyllactose trisaccharide. Then, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl propionate) (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in Example 3. The obtained solution was then stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome in which the DTSSP was bonded to the HSA on the liposome. Then, 50 μg of the glycosylamine compound of the 6′-sialyllactose trisaccharide was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 7.2) to bond the 6′-sialyllactose trisaccharide to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this manner, 3 types of liposomes (2 ml each), differing in the amount of sugar chain bonded thereto (referred to as 6SL-1 (50 μg), 6SL-2 (200 μg), and 6SL-3 (1 mg)), in which 6′-sialyllactose trisaccharide is bonded to the liposome through human serum albumin (
Bonding of 3′-Sialyllactosamine Saccharide to Human Serum Albumin (HSA) Bonded On Liposome Membrane Surfaces (3Types of Liposome Differing in the Amount of Sugar Chain Bonded)
50 μg, 200 μg, or 1 mg of 3′-sialyllactosamine saccharide (Wako Pure Chemical Co., Japan) was added to 0.5 ml of water solution having 0.25 g of NH4HCO3 dissolved therein, and the obtained solution was stirred at 37° C. for 3 days. Then, the solution was filtered by using a filter of 0.45 μm to complete an amination reaction at the reduction terminal of the sugar chain and obtain 50 μg of glycosylamine compound of the 3′-sialyllactosamine saccharide. Then, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl propionate) (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in Example 3. The obtained solution was then stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome in which the DTSSP was bonded to the HSA on the liposome. Then, 50 μg of the glycosylamine compound of the 3′-sialyllactosamine saccharide was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 7.2) to bond the 3′-sialyllactosamine saccharide to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this manner, 3 types of liposomes (2 ml each), differing in the amount of sugar chain bonded thereto (referred to as 3SLN-1 (50 μg), 3SLN-2 (200 μg), and 3SLN-3 (1 mg)), in which 3′-sialyllactosamine saccharide is bonded to the liposome through human serum albumin (
Bonding of 6′-Sialyllactosamine Saccharide to Human Serum Albumin (HSA) Bonded On Liposome Membrane Surfaces (3Types of Liposome Differing in the Amount of Sugar Chain Bonded)
50 μg, 200 μg, or 1 mg of 6′-sialyllactosamine saccharide (Wako Pure Chemical Co., Japan) was added to 0.5 ml of water solution having 0.25 g of NH4HCO3 dissolved therein, and the obtained solution was stirred at 37° C. for 3 days. Then, the solution was filtered by using a filter of 0.45 μm to complete an amination reaction at the reduction terminal of the sugar chain and obtain 50 μg of glycosylamine compound of the 6′-sialyllactosamine saccharide. Then, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl propionate) (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in Example 3. The obtained solution was then stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome in which the DTSSP was bonded to the HSA on the liposome. Then, 50 μg of the glycosylamine compound of the 6′-sialyllactosamine saccharide was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM 300 membrane and a PBS buffer solution (pH 7.2) to bond the 6′-sialyllactosamine saccharide to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this manner, 3 types of liposomes (2 ml each), differing in the amount of sugar chain bonded thereto (referred to as 6SLN-1 (50 μg), 6SLN-2 (200 μg), and 6SLN-3 (1 mg)), in which 6′-sialyllactosamine saccharide is bonded to the liposome through human serum albumin (
Hydrophilization of Human Serum Albumin Bonded on Liposome Membrane (HSA) Surface
For the 12 types of sugar-bonded liposomes prepared in Example 34 to 37, the respective HSA protein surface were separately hydrophilized through the following process. 13 mg of tris(hydroxymethyl)aminomethane was added to each of the 12 types of sugar chain-binding liposomes (2 ml each). The respective obtained solutions were stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. The solutions were then subjected to ultrafiltration by using an XM300 membrane and a PBS buffer solution (pH 7.2) to remove unreacted materials. In this manner, 2 ml of final product for each of the 12 types of hydrophilized sugar chain-binding liposome complexes (referred to as: 3SL-2, 3SL-2, 3SL-3, 6SL-1, 6SL-2, 6SL-3, 3SLN-1, 3SLN-2, 3SLN-3, 6SLN-1, 6SLN-2, 6SLN-3) (total lipid mass: 2 mg, total protein mass: 200 μg, average particle size: 100 nm) were obtained.
Measurement of Lectin-Binding Activity Inhibiting Effect in Each Type of Sugar Chain-Binding Liposome Complex
The in vitro lectin-binding activity of each of the 12 types of hydrophilized sugar chain-binding liposomes prepared in Examples 34 to 37 was measured through an inhibition test using a lectin-immobilized microplate by methods known in the art (Yamazaki, N. (1999) Drug Delivery System, 14, 498-505). More specifically, a lectin (E-selectin; R&D Systems Co., USA) was immobilized on a 96 well-microplate. Then, 0.1 μg of biotinylated and fucosylated fetuin as a comparative ligand, and various types of sugar chain-binding liposome complexes having different densities (each including 0.01 μg, 0.04 μg, 0.11 μg, 0.33 μg or 1 μg of protein), were placed on the lectin-immobilized plate, and incubated at 4° C. for 2 hours. After washing with PBS (pH 7.2) three times, horseradish peroxidase (HRPO)-conjugated streptavidin was added to each of the wells. The respective test solutions were incubated at 4° C. for 1 hour, and then washed with PBS (pH 7.2) three times. Then, peroxidase substrates were added to the test solutions, and incubated at room temperature. Then, the absorbance at 405 nm of each of the test solutions was determined by a microplate reader (Molecular Devices Corp., USA). For the biotinylation of the fucosylated fetuin, each of the test solutions was subjected to a sulfo-NHS-biotin reagent (Pierce Co., USA) treatment and refined by using a Centricon-30 (Amicon Co., USA). HRPO-conjugated streptavidin was prepared by oxidizing HRPO and bonding streptavidin to the oxidized HRPO through a reductive amination method using NaBH3CN. This measurement result is shown in Table 3.
[Table 3]
Intestine Tract Absorption Control Liposome
125I-Labeling of Each Type of Sugar Chain-Binding Liposome Through the Chloramine T Method
A chloramine T (Wako Pure Chemical Co., Japan) solution and a sodium disulfite solution were prepared at 3 mg/ml and 5 mg/ml, respectively. 50 μl of the 13 different types of hydrophilized sugar chain-binding liposomes prepared in Examples 34 to 37, and Example 12, were put into separate Eppendorf tubes. Then, 15 μl of 125I-NaI (NEN Life Science Product, Inc. USA) and 10 μl of chloramine T solution were added thereto and reacted therewith. 10 μl of chloramine T solution was added to the respective solutions every 5 minutes. After 15 minutes from the completion of the above procedure repeated twice, 100 μl of sodium disulfite serving as a reducer was added to the solutions to stop the reaction. Then, each of the resulting solutions was placed on a Sephadex G-50 (Phramacia Biotech. Sweden) column chromatography, and eluted by PBS to purify a labeled compound. Finally, a non-labeled liposome complex was added to each of the solutions to adjust a specific activity (4×106 Bq/mg protein). In this manner, 13 types of 125I-labeled liposome solutions were obtained.
Measurement of Transfer Rate of Each Type of Sugar Chain-Binding Liposome Complex from Intestine Tract to Blood Stream of Mice
Using an oral sonde, 13 different types of 125I-labeled, sugar-modified and tris(hydroxymethyl)aminomethane bonded liposome complexes of Example 40 were forcibly administered to the intestinal tract of male ddY mice (7 weeks of age) which had abstained from food, except for water, for one whole day, in an amount of 0.2 ml which is equivalent to 3 μg of protein per mouse. After 10 minutes, 1 ml of blood was taken from descending aorta under Nembutal anesthesia. Then, 125I-radioactivity in the blood was measured with a gamma counter (Alola ARC300). Further, in order to check the in vivo stability of each type of liposome complex, serum from each mouse's blood was subjected to chromatography using a Sephadex G-50. As a result, most of the radioactivity in each sample of serum was found in void fractions having a high molecular weight, and it was proved that each type of liposome complexes has a high in vivo stability. The radioactivity transfer rate from intestinal tract to blood was represented by the ratio of the radioactivity per ml of blood to the total of given radioactivity (% dose/ml blood). This measurement result is shown in FIGS. 48 to 52.
Preparation of Liposome Encapsulating Anti-Cancer Agene Doxorubicin
Liposome was prepared by using the cholate dialysis based method. More specifically, 46.9 mg of sodium cholate was added to 45.6 mg of lipid mixture consisting of dipalmitoylphosphatidylcholine, cholesterol, dicetylphosphate, ganglioside and dipalmitoylphosphatidylethanolamine at a molar ratio of 35:40:5:15:5, respectively, and the lipid mixture was dissolved in 3 ml of chloroform/methanol solution. The solution was then evaporated, and the resulting deposit was dried in vacuo to obtain a lipid membrane. The obtained lipid membrane was suspended in 10 ml of a TAPS buffered saline solution (pH 8.4), and was subjected to a supersonic treatment to obtain 10 ml of a clear micelle suspension. Then, anticancer drug doxorubicin, completely dissolved in the TAPS buffer solution (pH 8.4) at 3 mg/ml, was added dropwise slowly to this micelle suspension while stirring. After being mixed homogeneously, this micelle suspension containing doxorubicin was subjected to ultrafiltration by using a PM10 membrane (Amicon Co., USA) and the TAPS buffered saline solution (pH 8.4) to prepare 10 ml of a uniform suspension of the liposome encapsulating anticancer drug doxorubicin. The liposome encapsulating anticancer drug doxorubicin in the resulting physiological saline suspension (37° C.) thus obtained was subjected to analysis for the particle diameter and zeta potential using a measuring device for zeta potential, particle diameter and molecular weight (Model Nano ZS, Malvern Instrumentss Ltd., UK) and the particle diameter was 50 to 350 nm and the zeta potential was −30 to −10 mV.
Hydrophilization of Lipid Membrane Surface of Liposomes Encapsulating Anticancer Drug Doxorubicin
10 ml of the liposome solution containing anticancer drug doxorubicin prepared in Example 42 was subjected to ultrafiltration using an XM300 membrane (Amicon Co., USA) and a CBS buffer solution (pH 8.5) to adjust the pH of the solution to 8.5. Then, 10 ml of bis(sulfosuccinimidyl) suberate (BS3; Pierce Co., USA) crosslinking reagent was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night to complete the reaction between the BS3 and the dipalmitoylphosphatidyletanolamine of the lipid on the liposome membrane. This liposome solution was then subjected to ultrafiltration by using an XM300 membrane and a CBS buffer solution (pH 8.5). Then, 40 mg of tris(hydroxymethyl)aminomethane dissolved in 1 ml of CBS buffer solution (pH 8.5) was added to 10 ml of the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and stirred at 7° C. for one night to complete the chemical bonding reaction between the BS3 bonded to the lipid on the liposome membrane and the tris(hydroxymethyl)aminomethane. In this manner, the hydroxyl groups of the tris(hydroxymethyl)aminomethane were coordinated on the lipid dipalmitoylphosphatidyletanolamine of the liposome membrane encapsulating the anticancer drug doxorubcin to achieve the hydrophilization thereof.
Bonding of Human Serum Albumin (HSA) to Membrane Surface of Liposomes Encapsulating Anticancer Drug Doxorubicin
A coupling reaction method based on a previously reported method (Yamazaki, N., Kodama, M. and Gabius, H.-J. (1994) Methods Enzymol. 242, 56-65) was used. More specifically, the reaction was carried out through a two-stage reaction method. That is, 43 mg of sodium metaperiodate dissolved in 1 ml of TAPS buffer solution (pH 8.4) was added to 10 ml of the liposome obtained in Example 2, and the obtained solution was stirred at room temperature for 2 hours to periodate-oxidize the ganglioside on the membrane surface of the liposome. Then, the solution was subjected to ultrafiltration by using an XM300 membrane and a PBS buffer solution (pH 8.0) to obtain 10 ml of oxidized liposome. 20 mg of human serum albumin (HSA) was then added to the liposome solution, and the obtained solution was stirred at 25° C. for 2 hours. Then, 100 μl of 2M NaBH3CN was added to the PBS buffer solution (pH 8.0), and the obtained solution was stirred at 10° C. for one night to bond the HSA to the liposome membrane surface through a coupling reaction between the HSA and the ganglioside on the liposome. Then, 10 ml of the solution of the HSA-bonded liposome encapsulating anticancer drug doxorubicin was obtained through an ultrafiltration using an XM300 membrane and a CBS buffer solution (pH 8.5).
Bonding of α-1-6 Mannobiose disaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces and Hydrophilization of Linker Protein (HAS)
50 μg of α-1,6-mannobiose disaccharide (Calbiochem Co., USA) was added to 0.5 ml of water solution having 0.25 g of NH4HCO3 dissolved therein, and the obtained solution was stirred at 37° C. for 3 days. Then, the solution was filtered by using a filter of 0.45 μm to complete an amination at the reduced terminal of the sugar chain and obtain 50 μg of glycosylamine compound of the α-1,6-mannobiose disaccharide. Then, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl propionate) (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the solution of the liposome encapsulating anticancer drug doxorubicin obtained in Example 44. The obtained solution was then stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome in which the DTSSP was bonded to the HSA on the liposome. Then, 50 μg of the glycosylamine compound of the α-1,6-mannobiose disaccharide was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM300 membrane and a PBS buffer solution (pH 7.2) to bond the α-1,6-mannobiose to the DTSSP on the human serum albumin bonded on the liposome membrane surface. 13 mg of tris(hydroxymethyl)aminomethane was added to this liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. The solutions were then subjected to ultrafiltration by using an XM300 membrane and a PBS buffer solution (pH 7.2) to bond tris(hydroxymethyl)aminomethane to the DTSSP on the human serum albumin bonded on the liposome membrane surface. As the result, the liposome shown in
Bonding of 3-Fucosyllactose Trisaccharide to Human Serum Albumin (HSA) Bonded on Liposome Membrane Surfaces and Hydrophilization of Linker Protein (HAS)
50 μg of 3-fucosyllactose trisaccharide (Calbiochem Co., USA) was added to 0.5 ml of water solution having 0.25 g of NH4HCO3 dissolved therein, and the obtained solution was stirred at 37° C. for 3 days. Then, the solution was filtered by using a filter of 0.45 μm to complete an amination at the reduced terminal of the sugar chain and obtain 50 μg of glycosylamine compound of the α-1,6-mannobiose disaccharide. Then, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl propionate) (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the solution of the liposome encapsulating anticancer drug doxorubicin obtained in Example 44. The obtained solution was then stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome in which the DTSSP was bonded to the HSA on the liposome. Then, 50 μg of the glycosylamine compound of the 3-fucosyllactose trisaccharide was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM300 membrane and a PBS buffer solution (pH 7.2) to bond the 3-fucosyllactose trisaccharide to the DTSSP on the human serum albumin bonded on the liposome membrane surface. 13 mg of tris(hydroxymethyl)aminomethane was added to this liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. The solutions were then subjected to ultrafiltration by using an XM300 membrane and a PBS buffer solution (pH 7.2) to bond tris(hydroxymethyl)aminomethane to the DTSSP on the human serum albumin bonded on the liposome membrane surface. As the result, the liposome shown in
Hydrophilization of Linker Protein (HSA) by the Bonding of Tris(Hydroxymethyl)Aminomethane to Human Serum Albumin (HSA) Bonded on Membrane Surfaces of Liposome Encapsulating Anticancer Drug Doxorubicin
To prepare liposome encapsulating anticancer drug doxorubicin as a comparative sample, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl)propionate (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the solution of the liposome encapsulating anticancer drug doxorubicin obtained in Example 44. The obtained solution was then stirred at 25° C. for 2 hours and subsequently stirred at 7° C. for one night. Then the solution was subjected to ultrafiltration by using an XM300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of liposome with the hydrophylized linker protein (HSA) in which DTSPP was bonded to the HSA on the liposome. 13 mg of tris(hydroxymethyl)aminomethane (Wako Co., Japan) was added to this liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. The solutions were then subjected to ultrafiltration by using an XM300 membrane and a PBS buffer solution (pH 7.2) to bond tris(hydroxymethyl)aminomethane to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this manner, 2 ml of the liposome encapsulating the anticancer drug doxorubicin with the hydrophilized linker protein (HSA), in which tris(hydroxymethyl)aminomethane, human serum albumin and liposome were bonded, (abbreviated as DX-TRIS) (total lipid mass: 2 mg, total protein mass: 200 μg) shown in
Measurement of Carcinostatic Effect by Tail Vein Administration of Each Type of Sugar Chain-Binding Liposome Complex in Mice with Cancer
Ehrlich ascites tumor (EAT) cells (about 2×107 cells) were implanted subcutaneously into the right femoral region in male ddY mice (7 weeks of age), and the 40 mice were used in this test after the tumor tissues grew to 50 to 100 cubic mm (after 6 to 8 days). These mice with cancer were separated into 4 groups, 10 mice in each group. Mice in each group were injected with the sugar chain-binding liposome complex containing anticancer drug doxorubicin prepared in Example 45, the liposome without sugar-modification containing anticancer drug doxorubicin prepared in Example 47, physiological saline or free doxorubicin solution into the tail veins in an amount of 0.2 ml per mouse every 3 to 4 days 4 times (7, 11, 14 and 18 days after implantation of cancer cells). The volume of the cancer was calculated from the following formula by measuring the major axis (L) and the minor axis (S) with a vernier caliper:
Cancer Volume (cubic mm)=1/2×L×S×S.
The results are shown in
Measurement of Carcinostatic Effect by Oral Administration of Each Type of Sugar Chain-Binding Liposome Complex in Mice with Cancer
Ehrlich ascites tumor (EAT) cells (about 2×107 cells) were implanted subcutaneously into the right femoral region in male ddY mice (7 weeks of age), and the 30 mice were used in this test after the tumor tissues grew to 50 to 100 cubic mm (after 6 to 8 days). These mice with cancer were separated into three groups, 10 mice in each group. Mice in each group were orally administered with the sugar chain-binding liposome complex containing anticancer drug doxorubicin prepared in Example 46, the liposome without sugar-modification containing anticancer drug doxorubicin prepared in Example 34 or physiological saline in an amount of 0.6 ml per mouse every 3 to 4 days 4 times (7, 11, 14 and 18 days after implantation of cancer cells). The volume of the cancer was calculated from the following formula by measuring the major axis (L) and the minor axis (S) with a vernier caliper:
Cancer Volume (cubic mm)=1/2×L×S×S.
The results are shown in
Investigation of Pharmacokinetics and Carcinostatic Effect in Mice with Cancer
(1) Preparation of Liposome Having Glycolipid Type Sugar Chain and Containing Doxorubicin, and Assay for Encapsulated Drug, and Storage Stability
Liposome was prepared by using the cholate dialysis based method. More specifically, 46.9 mg of sodium cholate was added to 45.6 mg of lipid mixture consisting of dipalmitoylphosphatidylcholine, cholesterol, dicetylphosphate, ganglioside (containing GM1: 13%, GD1a: 38%, GD1b: 9%, GT1b: 16% as glycolipid sugar chain) and at a molar ratio of 35:45:5:15, respectively, and the lipid mixture was dissolved in 3 ml of chloroform/methanol solution. The solution was then evaporated, and the resulting deposit was dried in vacuo to obtain a lipid membrane. The obtained lipid membrane was suspended in 3 ml of a TAPS buffered solution (pH 8.4), and was subjected to a supersonic treatment to obtain 3 ml of a clear micelle suspension. To this micelle suspension, PBS buffer solution (pH 7.2) was added to bring up the volume to 10 ml. Then, anticancer drug doxorubicin, completely dissolved in the TAPS buffer solution (pH 8.4) at 3 mg/ml, was added dropwise slowly to this micelle suspension while stirring. After being mixed homogeneously, this micelle suspension containing doxorubicin was subjected to ultrafiltration by using a PM10 membrane (Amicon Co., USA) and the TAPS buffered saline solution (pH 8.4) to prepare 10 ml of a uniform suspension of the liposome encapsulating anticancer drug doxorubicin. The liposome encapsulating anticancer drug doxorubicin in a physiological saline suspension (37° C.) thus obtained was subjected to analysis for the particle diameter and zeta potential using a measuring device for zeta potential, particle diameter and molecular weight (Model Nano ZS, Malvern Instruments Ltd., UK) and the particle diameter was 50 to 350 nm and the zeta potential was −30 to −10 mV. Measuring the amount of encapsulated drug in the liposome with absorbance at 485 nm revealed that doxorubicin was incorporated at the concentration of about 71 μg/ml. This liposome encapsulating doxorubicin was stable in a refrigerator after 1 year storage without precipitating or aggregating.
(2) Measurement of Pharmacokinetics of Liposome Having Glycolipid Type Sugar Chain and Doxorubicin by Tail Vein Administration in Mice with Cancer
Ehrlich ascites tumor (EAT) cells (about 2×107 cells) were implanted subcutaneously into the right femoral region in male ddY mice (7 weeks of age), and the 50 mice were used in this test after the tumor tissues grew to 50 to 100 cubic mm (after 6 to 8 days).
These mice with cancer were separated into two groups, 25 mice per each group, and the mice in each group were injected with a liposome solution encapsulating having glycolipid type sugar chain and doxorubicin or free doxorubicin solution at a dose of 0.2 ml in tail vein after the tumor implant. Then, at various time intervals, the doxorubicin concentration was measured by fluorescent method (470 nm) in blood and tumor tissue of 5 mice from each group. Also the area under the concentration-time curves (AUC) of the drug in blood was measured and the distribution of doxorubicin in tumor tissues and cells was observed under a fluorescent microscope. As shown clearly in the graphs and photographs in Table 4 and
(3) Measurement of Carcinostatic Effect of Liposome Having Glycolipid Type Sugar Chain and Doxorubicin by Tail Vein Administration in Mice with Cancer
Ehrlich ascites tumor (EAT) cells (about 2×107 cells) were implanted subcutaneously into the right femoral region in male ddY mice (7 weeks of age), and the 30 mice were used in this test after the tumor tissues grew to 50 to 100 cubic mm (after 6 to 8 days). These mice with cancer were separated into 3 groups, 10 mice in each group. Mice in each group were injected with liposome having glycolipid type sugar chain and doxorubicin or free doxorubicin solution or physiological saline at a dose of 0.2 ml through tail vein after the tumor implant. The injections were carried out every 3-4 days for total of 6 times. The volume of the cancer was calculated from the following formula by measuring the major axis (L) and the minor axis (S) of transplanted tumor with a vernier caliper:
Cancer Volume (cubic mm)=1/2×L×S×S.
As shown in the graphs and photographs of FIGS. 57 to 62, by using the liposome encapsulating doxorubicin of the present invention, in comparison with the conventional free doxorubicin, the increase in the tumor volume was inhibited several folds stronger even administering at a low concentration, indicating a marked carcinostatic effect.
[Table 4]
Investigation of Blood Retention of Liposome Treated with 2 Kinds of Hydrophilization
(1) Preparation of Liposome
Liposome was prepared by using the cholate dialysis based method. More specifically, 46.9 mg of sodium cholate was added to 45.6 mg in total of lipid mixture consisting of dipalmitoylphosphatidylcholine, cholesterol, dicetylphosphate, ganglioside and dipalmitoylphosphatidylethanolamine at a molar ratio of 35:40:5:15:5, respectively, and the lipid mixture was dissolved in 3 ml of chloroform/methanol solution. The solution was then evaporated, and the resulting deposit was dried in vacuo to obtain a lipid membrane. The obtained lipid membrane was suspended in 3 ml of a TAPS buffer solution (pH 8.4), and was subjected to a supersonic treatment to obtain 3 ml of a clear micelle suspension. To this miocelle suspension, PBS buffer solution (pH 7.2) was added to bring up the volume to 5 ml. Then, predonisolone phosphate, completely dissolved in the TAPS buffer solution (pH 8.4) at 2250 mg/6 ml, was added dropwise slowly to this micelle suspension while stirring. After being mixed homogeneously, this micelle suspension containing predonisolone phosphate was subjected to ultrafiltration by using a PM10 membrane (Amicon Co., USA) and the TAPS buffer solution (pH 8.4) to prepare 10 ml of a uniform liposome. The liposome particles in the resulting physiological saline suspension (37° C.) was subjected to analysis for the particle diameter and zeta potential using a measuring device for zeta potential, particle diameter and molecular weight (Model Nano ZS, Malvern Instruments Ltd., UK) and the particle diameter was 50 to 350 nm and the zeta potential was −30 to −10 mV
(2) Hydrophilization of Lipid Membrane Surface of Liposomes by Tris(Hydroxymethyl)Aminomethane
10 ml of the liposome solution prepared in (1) was subjected to ultrafiltration by using an XM300 membrane (Amicon Co., USA) and a CBS buffer solution (pH 8.5) to adjust the pH of the solution to 8.5. Then, 10 ml of bis(sulfosuccinimidyl) suberate (BS3; Pierce Co., USA) crosslinking reagent was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night to complete the chemical bonding reaction between the dipalmitoylphosphatidyletanolamine of the lipid on the liposome membrane and the BS3. This liposome solution was then subjected to ultrafiltration by using an XM300 membrane and a CBS buffer solution (pH 8.5). Then, 40 mg of tris(hydroxymethyl)aminomethane dissolved in 1 ml of CBS buffer solution (pH 8.5) was added to 10 ml of the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and stirred at 7° C. for one night to complete the chemical bonding reaction between the BS3 bonded to the lipid on the liposome membrane and the tris(hydroxymethyl)aminomethane. In this manner, the hydroxyl groups of the tris(hydroxymethyl)aminomethane were coordinated on the dipalmitoylphosphatidyletanolamine of the lipid on the liposome membrane to achieve the hydrophilization of the lipid membrane surface of the liposome.
(3) Hydrophilization by Cellobiose on Lipid Membrane Surface of Liposome
10 ml of the liposome solution prepared in (1) was subjected to ultrafiltration by using an XM300 membrane (Amicon Co., USA) and a CBS buffer solution (pH 8.5) to adjust the pH of the solution to 8.5. Then, 10 ml of bis(sulfosuccinimidyl) suberate (BS3; Pierce Co., USA) crosslinking reagent was added to the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night to complete the chemical bonding reaction between the dipalmitoylphosphatidyletanolamine of the lipid on the liposome membrane and the BS3. This liposome solution was then subjected to ultrafiltration by using an XM300 membrane and a CBS buffer solution (pH 8.5). Then, 50 mg of cellobiose dissolved in 1 ml of CBS buffer solution (pH 8.5) was added to 10 ml of the liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and stirred at 7° C. for one night to complete the chemical bonding reaction between the BS3 bonded to the lipid on the liposome membrane and cellobiose. In this manner, the hydroxyl groups of cellobiose were coordinated on the dipalmitoylphosphatidyletanolamine of the lipid on the liposome membrane to achieve the hydrophilization of the lipid membrane surface of the liposome.
(4) Bonding of Human Serum Albumin (HSA) to Tris(Hydroxymethyl)Aminomethane Bonded on Liposome Membrane Surface
A coupling reaction method based on a previously reported method (Yamazaki, N., Kodama, M. and Gabius, H.-J. (1994) Methods Enzymol. 242, 56-65) was used. More specifically, the reaction was carried out through a two-stage chemical reaction. That is, 43 mg of sodium metaperiodate dissolved in 1 ml of TAPS buffer solution (pH 8.4) was added to 10 ml of the liposome obtained in (2), and the obtained solution was stirred at room temperature for 2 hours to periodate-oxidize the ganglioside on the membrane surface of the liposome. Then, the solution was subjected to ultrafiltration by using an XM300 membrane and a PBS buffer solution (pH 8.0) to obtain 10 ml of oxidized liposome. 20 mg of human serum albumin (HSA) was then added to the liposome solution, and the obtained solution was stirred at 25° C. for 2 hours. Then, 100 μl of 2M NaBH3CN was added to the PBS buffer solution (pH 8.0), and the obtained solution was stirred at 10° C. for one night to bond the HSA to the liposome membrane surface through a coupling reaction between the HSA and the ganglioside on the liposome. Then, 10 ml of HSA-bonded liposome solution was obtained through an ultrafiltration using an XM300 membrane and a CBS buffer solution (pH 8.5).
(5) Bonding of Human Serum Albumin (HSA) to Cellobiose Bonded on Liposome Membrane Surface
A coupling reaction method based on a previously reported method (Yamazaki, N., Kodama, M. and Gabius, H.-J. (1994) Methods Enzymol. 242, 56-65) was used. More specifically, the reaction was carried out through a two-stage chemical reaction. That is, 43 mg of sodium metaperiodate dissolved in 1 ml of TAPS buffer solution (pH 8.4) was added to 10 ml of the liposome obtained in Example 3, and the obtained solution was stirred at room temperature for 2 hours to periodate-oxidize the ganglioside on the membrane surface of the liposome. Then, the solution was subjected to ultrafiltration by using an XM300 membrane and a PBS buffer solution (pH 8.0) to obtain 10 ml of oxidized liposome. 20 mg of human serum albumin (HSA) was then added to the liposome solution, and the obtained solution was stirred at 25° C. for 2 hours. Then, 100 μl of 2M NaBH3CN was added to the PBS (pH 8.0), and the obtained solution was stirred at 10° C. for one night to bond the HSA to the liposome membrane surface through a coupling reaction between the HSA and the ganglioside on the liposome. Then, 10 ml of HSA-bonded liposome solution was obtained through an ultrafiltration using an XM300 membrane and a CBS buffer solution (pH 8.5).
(6) Hydrophilization of Linker Protein (HSA) by Bonding of Tris(Hydroxymethyl)Aminomethane on Human Serum Albumin (HSA) Bonded to Liposome Membrane Surface
To prepare liposome as one of the hydrophilized samples, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl)propionate (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in (4). The obtained solution was then stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of hydrophilized liposome in which the DTSSP was bonded to the HSA on the liposome. 13 mg of tris(hydroxymethyl)aminomethane (Wako Co., Japan) was added to this liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. The solutions were then subjected to ultrafiltration by using an XM300 membrane and a PBS buffer solution (pH 7.2) to bond tris(hydroxymethyl)aminomethane to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this manner, 2 ml of the liposome with the hydrophilized linker protein (HSA), in which tris(hydroxymethyl)aminomethane, human serum albumin and liposome were bonded, (total lipid mass: 2 mg, total protein mass: 200 μg) was obtained as a comparative sample. The liposome particles in the resulting physiological saline suspension (37° C.) were subjected to analysis for the particle diameter and zeta potential using a measuring device for zeta potential, particle diameter and molecular weight (Model Nano ZS, Malvern Instruments Ltd., UK) and the particle diameter was 50 to 350 nm and the zeta potential was −30 to −10 mV
(7) Hydrophilization of Linker Protein (HSA) by Bonding of Cellobiose on Human Serum Albumin (HSA) Bonded to Liposome Membrane Surface
To prepare liposome as one of the hydrophilized samples, 1 mg of 3,3′-dithiobis(sulfosuccinimidyl)propionate (DTSSP; Pierce Co., USA) serving as a crosslinking reagent was added to 1 ml of a part of the liposome solution obtained in (5). The obtained solution was then stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. Then, the solution was subjected to ultrafiltration by using an XM300 membrane and a CBS buffer solution (pH 8.5) to obtain 1 ml of hydrophilized liposome in which the DTSSP was bonded to the HSA on the liposome. 30 mg of cellobiose was added to this liposome solution. The obtained solution was stirred at 25° C. for 2 hours, and subsequently stirred at 7° C. for one night. The solutions were then subjected to ultrafiltration by using an XM300 membrane and a PBS buffer solution (pH 7.2) to bond cellobiose to the DTSSP on the human serum albumin bonded on the liposome membrane surface. In this manner, 2 ml of the liposome with the hydrophilized linker protein (HSA), in which cellobiose, human serum albumin and liposome were bonded, (total lipid mass: 2 mg, total protein mass: 200 μg) was obtained as a hydrophilized sample. The liposome particles in the resulting physiological saline solution (37° C.) were subjected to analysis for the particle diameter and zeta potential using a measuring device for zeta potential, particle diameter and molecular weight (Model Nano ZS, Malvern Instruments Ltd., UK) and the particle diameter was 50 to 350 nm and the zeta potential was −30 to −10 mV.
(8) Preparation of Liposome without Hydrophilization
Liposome was prepared by using the cholate dialysis based method. More specifically, 46.9 mg of sodium cholate was added to 45.6 mg of lipid mixture consisting of dipalmitoylphosphatidylcholine, cholesterol, dicetylphosphate and ganglioside (containing 100% of GT1b as glycolipid sugar chain) at a molar ratio of 35:45:5:15, respectively, and the lipid mixture was dissolved in 3 ml of chloroform/methanol solution. The solution was then evaporated, and the resulting deposit was dried in vacuo to obtain a lipid membrane. The obtained lipid membrane was suspended in 3 ml of a TAPS buffer solution (pH 8.4), and was subjected to a supersonic treatment to obtain 3 ml of a clear micelle suspension. Then, to this micelle suspension, PBS buffer solution (pH 7.2) was added to bring up the volume to 10 ml, and doxorubicin, completely dissolved in the TAPS buffer solution (pH 8.4) at 3 mg/l ml, was added dropwise slowly to this micelle suspension while stirring. After being mixed homogeneously, this micelle suspension containing doxorubicin was subjected to ultrafiltration by using a PM10 membrane (Amicon Co., USA) and the TAPS buffer solution (pH 8.4) to prepare 10 ml of a uniform suspension of the liposome particles without hydrophilization. The liposome particles without hydrophilization in the resulting physiological saline suspension (37° C.) were subjected to analysis for the particle diameter and zeta potential using a measuring device for zeta potential, particle diameter and molecular weight (Model Nano ZS, Malvern Instruments Ltd., UK) and the particle diameter was 50 to 350 nm and the zeta potential was −30 to −10 mV
(9) 125I-Labeling of Liposome Through the Chloramine T Method
A chloramine T (Wako Pure Chemical Co., Japan) solution and a sodium disulfite solution were prepared at 3 mg/ml and 5 mg/ml, respectively. 50 μl of the 3 different types of liposomes prepared in Examples 20 to 22 were put into separate Eppendorf tubes. Then, 15 μl of 125I-NaI (NEN Life Science Product, Inc. USA) and 10 μl of chloramine T solution were added thereto and reacted therewith. 10 μl of chloramine T solution was added to the respective solutions every 5 minutes. After 15 minutes from the completion of the above procedure repeated twice, 100 μl of sodium disulfite serving as a reducer was added to the solutions to stop the reaction. Then, each of the resulting solutions was placed on a Sephadex G-50 (Phramacia Biotech. Sweden) column chromatography, and eluted by PBS to purify a labeled compound. Finally, a non-labeled liposome complex was added to each of the solutions to adjust a specific activity (4×106 Bq/mg protein). In this manner, three types of 125I-labeled liposome solutions were obtained.
(10) Measurement of the Concentration of Different Types of Liposome in Blood Stream of Mice with Cancer
Ehrlich ascites tumor (EAT) cells (about 2×107 cells) were implanted subcutaneously into the femoral region in male ddY mice (7 weeks of age), and the mice were used in this test after the tumor tissues grew to 0.3 to 0.6 g (after 6 to 8 days). To this mice with cancer, 0.2 ml of three types of liposome complex labeled with 125I according to (9) were injected at a dose of 30 μg/mouse as lipid amount through tail vein. The blood sample was collected after 5 minutes and its radioactivity was measured with a gamma counter (Aloka ARC 300). Distribution of the radioactivity to the blood was expressed as a ratio of the radioactivity per 1 ml of blood to the total radioactivity administered (% administered amount/ml of blood). As shown in
Preparation of Liposome Encapsulating Vitamin A and Storage Stability
Liposome was prepared by using the cholate dialysis based method. More specifically, 46.9 mg of sodium cholate was added to 45.6 mg in total of lipid mixture consisting of dipalmitoylphosphatidylcholine, cholesterol, dicetylphosphate, ganglioside, sphingomyelin and dipalmitoylphosphatidylethanolamine at a molar ratio of 35:40:5:5:10:5, respectively, and the lipid mixture was dissolved in 3 ml of chloroform/methanol solution. The solution was then evaporated, and the resulting deposit was dried in vacuo to obtain a lipid membrane. The obtained lipid membrane was suspended in 3 ml of a PBS buffer solution (pH 7.2), and was subjected to a supersonic treatment to obtain 3 ml of a clear micelle suspension. Then, PBS buffer solution (pH 7.2) was added to bring up the volume to 10 ml, and 6 mg/ml of vitamin A, completely dissolved in 0.3 ml of ethanol and 0.7 ml of PBS buffer solution (pH 7.2), was added dropwise slowly to this micelle suspension while stirring. After being mixed homogeneously, this micelle suspension containing vitamin A was subjected to ultrafiltration by using a PM10 membrane (Amicon Co., USA) and the PBS buffer solution (pH 7.2) to prepare 10 ml of a uniform liposome encapsulating vitamin A (average particle size: 100 nm) suspension. This liposome encapsulating vitamin A was stable without precipitation or coagulation after storing 1 year in a refrigerator.
Preparation of Liposome Encapsulating Vitamin E and Storage Stability
Liposome was prepared by using the cholate dialysis based method. More specifically, 46.9 mg of sodium cholate was added to 45.6 mg in total of lipid mixture consisting of dipalmitoylphosphatidylcholine, cholesterol, dicetylphosphate, ganglioside, sphingomyelin and dipalmitoylphosphatidylethanolamine at a molar ratio of 35:40:5:5:10:5, respectively, 6 mg of vitamin E was added and the lipid mixture was dissolved in 3 ml of chloroform/methanol solution. The solution was then evaporated, and the resulting deposit was dried in vacuo to obtain a lipid membrane. The obtained lipid membrane was suspended in 3 ml of a PBS bugger solution (pH 7.2), and was subjected to a supersonic treatment to obtain 3 ml of a clear micelle suspension. Then, PBS buffer solution (pH 7.2) was slowly added to this micelle suspension while stirring to bring up the volume to 10 ml, and 6 mg/ml of vitamin A, completely dissolved in 0.3 ml ethanol and 0.7 ml of PBS buffer solution (pH 7.2), was added dropwise slowly to the suspension. After being mixed homogeneously, this micelle suspension containing vitamin A was subjected to ultrafiltration by using a PM10 membrane (Amicon Co., USA) and the PBS buffer solution (pH 7.2) to prepare 10 ml of a uniform liposome encapsulating vitamin A (average particle size: 100 nm) suspension. This liposome encapsulating vitamin E was stable without precipitation or coagulation after storing 1 year in a refrigerator.
The disclosures of all publications, patents and patent applications cited in the specification are entirely incorporated herein by reference.
A liposome having excellent stability was successfully obtained by controlling type and amount of composition constituting a liposome. Furthermore, a liposome having more excellent properties including stability than a conventional liposome was successfully obtained by hydrophilizing the liposome with a specific hydrophilic compound.
As shown in Examples of the present invention, liposomes were prepared by binding various types of sugar chains and a protein (linker) derived from a living organism including a human-derived protein such as human serum albumin, to the liposomes, and then, in-vivo dynamic of liposomes to various tissues in mice, particularly uptake of the liposomes into cancer tissues was analyzed by using Ehrlich's mice carrying solid cancer. As a result, it was found that in-vivo dynamic of liposomes to various tissues can be controlled (accelerated or suppressed) in an actual living body by using the difference in molecular structure of the sugar chains. Based on this, it was demonstrated that an efficient targeting ability to not only cancer tissues but also tissues of interest (such as blood, liver, spleen, lung, brain, small intestinal tract, heart, thymus gland, kidney, pancreas, muscle, large intestinal tract, bone, bone marrow, eyes, cancer tissue, inflammatory tissue and lymph node) can be added to a DDS material. As described above, the present invention successfully provides a liposome capable of controlling targetability, which is extremely useful in the medical/pharmaceutical field. Furthermore, a sugar-chain bonded liposome exhibiting excellent targetability was obtained by controlling the density of the sugar chain to be bonded to the surface of the liposome.
In addition, the sugar-chain modified liposome of the present invention has an epoch-making feature that it shows excellent intestinal absorption, in other words, it can be administered through a new administration route not observed in a conventional preparation using a liposome. Furthermore, intestinal absorption and in-vivo dynamics to various tissues (blood, liver, spleen, lung, brain, small intestinal tract, heart, thymus gland, kidney, pancreas, muscle, large intestinal tract, bone, bone marrow, eyes, cancer tissue, inflammatory tissue and lymph node) can be controlled by setting the amount and type of sugar chain bonded to a liposome. As a result, it is possible to efficiently and safely deliver a medicinal drug or a gene by way of the intestinal tract and blood to a living tissue without side effects. Hence, the liposome of the present invention is particularly useful in the medical/pharmaceutical field.
Moreover, when an anticancer drug is encapsulated in he hydrophilic liposome modified and unmodified by a sugar chain according to the present invention and administered to a subject orally or parenterally, the anticancer drug can be targeted to a cancer tissue and accumulated there, thereby suppressing growth of the cancer.
The targeting liposome of the present invention, when it encapsulates a compound having an appropriate medicinal effect therein, recognizes a lectin in vivo with the help of a sugar chain bonded on the surface of the liposome, and reaches a tissue/organ expressing the lectin. When the liposome is taken up by the cells of the tissue/organ, a compound having a medicinal effect produces its effects therein and works as a therapeutic drug and diagnostic drug. If an anticancer drug is encapsulated, the liposome is used as a therapeutic drug for cancer. Alternatively, the intestinal-absorption controlled liposome can be easily absorbed from the intestinal track. Therefore, a substance having a medicinal effect and encapsulated in the liposome can be swiftly produce its effect in vivo in the same manner as in the targeting liposome.
Number | Date | Country | Kind |
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2002-022575 | Jan 2002 | JP | national |
2002-022576 | Jan 2002 | JP | national |
This application is a continuation-in-part of copending application Ser. No. 10/352,914 filed on Jan. 29, 2003, the entire contents of which are hereby incorporated by reference.
Number | Date | Country | |
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Parent | 10352914 | Jan 2003 | US |
Child | 11350962 | Feb 2006 | US |