KR102036703B1 - Stem cell-nano drug delivery system complex and use thereof - Google Patents

Abstract

The present invention is a stem cell-nano anticancer agent loaded with carbon nanotube (CNT) and gold (Au) nanoparticle-based anticancer agents on the stem cell surface, which overcomes the existing stem cell side effects and target limitations of the nano anticancer agent and also has an excellent anticancer effect. To provide a complex.

Description

      Stem cell-nano drug delivery system complex and use

The present invention relates to a nanodrug delivery complex, and more particularly, to a stem cell-nano drug delivery complex and its use.

Currently, there are methods for treating cancer, such as treatment through surgery, radiation therapy and chemotherapy, but this may be accompanied by side effects or the treatment is limited depending on the progression of the cancer. As a result, the number increased in terms of quantity, but there was no significant change in quality. The reason for this is that most anticancer drugs act as a mechanism to stop and kill the cell cycles of proliferating cells, which in turn attacks the normally dividing cells in addition to cancer cells, leading to hair loss, loss of appetite, and white blood cells. This is because it causes a decrease in immunity. In order to minimize the side effects of these anticancer drugs, the development of target anticancer drugs is actively taking place. To date, more than 18 target anticancer drugs have been developed and applied to clinical trials. However, these target anticancer drugs have a limitation in that they can be effective in patients with specific targets even when the same type of cancer is used. Targeted drugs have to be administered over a long period of time, causing resistance. Cocktail therapy that combines powerful anticancer drugs with multiple targets at the same time, using a single anticancer drug to remove cancer in a short time, including the risk of causing serious side effects. Therefore, researches on anticancer drugs using gold nanoparticles, biodegradable polymers and carbon nanotubes as target therapeutics that can effectively treat cancer with few side effects are being actively conducted. In particular, nanoparticles are applicable to various biomedical fields including imaging, cancer treatment, etc. due to their mechanical, visual, and chemical properties. Carbon nanotubes as a drug carrier (drug carrier) has been mainly studied how to effectively deliver biological molecules into cells through endocytosis, the surface of the carbon nanotubes treated with polyethylene glycol (PEG) Thus, a method of loading an anticancer agent has been studied. In addition, nanoscale control of gold particles reveals new physicochemical properties that are not found in raw materials, which means that the smaller the size of the crystal, the greater the ratio of surface atoms to total atoms, which results in a large change in the thermodynamic properties of the material. Causes In general, the surface atoms of a solid material make a significant contribution to free energy compared to internal atoms. The increase in surface atoms alters thermodynamic properties such as melting of nanocrystals and phase transitions, and exhibits electromagnetic, optical, mechanical, and thermal properties. Since it is a base material of various nano devices such as transistors, light emitting devices, sensors, solar cells, and the like, it is used to manufacture anticancer drugs with improved anticancer drug treatment efficiency. For example, studies on gold nanoparticle-based anticancer agents that have functional groups on gold nanoparticles and loaded anticancer agents such as doxorubicin or paclitaxel on the surface of gold nanoparticles are being actively conducted.

In the case of conventional nanocancer drugs that have been developed for more effective anticancer drugs, the biodegradable polymers used in the formulation have been easily dissociated from the nanomaterials at acidic pH and blood conditions, and there is a limit to the anticancer drug delivery to the target site. Non-degradable nanoparticles, such as magnetic particles and carbon-based nanoparticles, have not been proven to be effective in overcoming toxic anticancer doses, and have disadvantages such as accumulation in reticular endothelial system (RES) organs. Nano-cancers still have challenges to solve. In this regard, Korean Patent No. 1711127 discloses a cancer-targeted anticancer agent-bonded iron oxide nanoparticle complex, a method for preparing the same, and a use thereof.

However, in the case of the prior art, there is a problem that the effect of the anticancer agent is reduced due to the low cancer targeting ability.

The present invention is to solve various problems including the above problems, and to provide a new type of stem cell-nano anticancer complex that overcomes the target limitations of conventional nano anticancer drugs and maximizes the efficacy of anticancer drugs. . However, these problems are exemplary, and the scope of the present invention is not limited thereby.

According to an aspect of the present invention, a stem cell-nano anticancer complex, in which carbon nanotubes (CNT) or gold (Au) nanoparticles loaded with an anticancer agent on a stem cell surface, are provided.

According to another aspect of the invention, there is provided an anticancer pharmaceutical composition containing the stem cell-nano anticancer complex as an active ingredient.

According to another aspect of the present invention, there is provided a method for treating cancer, comprising administering the therapeutically effective amount of a stem cell-nano anticancer complex to a subject with cancer.

According to one embodiment of the present invention made as described above, it is possible to maximize the efficacy of the anticancer agent and to implement a method for producing a new type of stem cell-nanoanticancer complex with improved target ability of the conventional nanoanticancer agent. Of course, the scope of the present invention is not limited by these effects.

1 schematically illustrates the preparation of a stem cell-nano anticancer complex loaded with carbon nanotube (CNT) -based and gold (Au) nano-based anticancer agents on the surface of mesenchymal stem cells (MSCs) according to an embodiment of the present invention. It is an illustration.
Figure 2 is a stem cell-carbon nanotube-based nano-cancer complex (hMSC-CD90-mwCNT-DOX) (A) and stem cell-gold nanoparticle-based nano-cancer complex prepared in accordance with an embodiment of the present invention (hMSC-CD90 -Au-DOX) (B) was prepared using confocal fluorescence microscopy to confirm that doxorubicin-coupled mwCNT and Au are properly attached to the stem cell surface and micrographs.
Figure 3 is a graph analyzing the degree of anticancer drug loading per cell of the stem cell-nano anticancer complex (hMSC-CD90-mwCNT-DOX) bound using an antibody that binds to the stem cell marker protein CD90.
Figure 4 analyzes the change of the anticancer drug load per cell of the stem cell-nano anticancer complex (hMSC-CD90-mwCNT-DOX, hMSC-CD73-mwCNT-DOX) bound using an antibody that binds to the stem cell marker protein CD90 or CD73 One graph.
Figure 5 is a graph of the anticancer agent persistence of the stem cell-nano anticancer complex (hMSC-CD90-mwCNT-DOX, hMSC-CD73-mwCNT-DOX) over time.
Figure 6 is a graph analyzing the change in cell viability of stem cells of the stem cell-nano anticancer complex (hMSC-CD90-mwCNT-DOX, hMSC-CD73-mwCNT-DOX).
Figure 7 is a graph analyzing the survival rate change of stem cells over time after the stem cell-nano anticancer complex (hMSC-CD90-mwCNT-DOX, hMSC-CD73-mwCNT-DOX) binding.
Figure 8 is a graph analyzing the intracellular calcium concentration change of the stem cell-nano anticancer complex (hMSC-CD90-mwCNT-DOX, hMSC-CD73-mwCNT-DOX).
9 is a confocal micrograph of MSC cell damage of stem cell-nano anticancer complexes (hMSC-CD90-mwCNT-DOX, hMSC-CD73-mwCNT-DOX) through changes in the expression of marker protein (E-cadherin). to be.
Figure 10 is a stem cell-nano anticancer complex (hMSC-CD90-mwCNT-DOX) of the present invention after the combination of confocal micrographs confirming the anti-cancer drug bound to the cell surface after the combination of cancer cells target capacity analysis by analyzing the stem cell- It is a graph analyzing the functionality of the nano-cancer drug complex.
11 is a graph analyzing the concentration of doxorubicin anticancer agent of the stem cell-nanoanticancer complex in which the nanoanticancer agent is loaded into the stem cells or combined with the stem cell membrane protein.
12 is a graph analyzing the loading degree of doxorubicin anticancer agent of the stem cell-nanoanticancer complex of the present invention.
Figure 13 is a graph analyzing the target capacity of the stem cell-nano anticancer complex of the present invention to non-small cell lung cancer cell lines (A549 and H1975).
Figure 14 is a graph comparing the self-toxicity between the stem cells of the MSC intracellular CNT-DOX uploading experimental group and MSC conjugation CNT-DOX experimental group.
Figure 15 compares the time-dependent lung cancer cells (H1975) killing capacity of the MSC medium treatment group, MSC treatment group, MSC intracellular CNT-DOX uploading experimental group, MSC conjugation CNT-DOX experimental group and control group for a long time according to an embodiment of the present invention Analyzed flow cytometry data.
Figure 16 analyzes the ability to kill the lung cancer cells (H1975) for a long time in the MSC medium treatment group, MSC treatment group, MSC intracellular CNT-DOX uploading experimental group, MSC conjugation CNT-DOX experimental group and the control group according to an embodiment of the present invention. One graph.
Figure 17 is a graph analyzing the killing capacity of stem cells in the MSC medium treatment group, MSC treatment group, MSC intracellular CNT-DOX uploading experimental group, MSC conjugation CNT-DOX experimental group and the control group.
Figure 18 was treated with lung cancer cell lines in MSC media treatment group, MSC treatment group, MSC intracellular CNT-DOX uploading experimental group, MSC conjugation CNT-DOX experimental group and control group for 240 hours using cancer cell marker proteins (CD 31, 34) It is a graph analyzing the reverse differentiation of stem cells into cancer cells.
19 is a graph of intracellular calcium signaling changes of the stem cell-nano anticancer complex and the MSC control group in which the nano-cancer agent is loaded into the stem cells or combined with the stem cell membrane protein.
FIG. 20 is a graph illustrating changes in calcium signaling between cells after treatment with a lung cancer cell line (H1975), in which a stem cell-nano anticancer complex and an MSC control group in which a nano anticancer agent is loaded into a stem cell or combined with a stem cell membrane protein.
Figure 21 is a graph analyzing the changes in calcium signaling between cells after the treatment of the cancer cell line (H1975) with a stem cell-nano anticancer complex and an MSC control group loaded with nano anticancer agents or stem cell membrane proteins into stem cells.
FIG. 22 is a schematic diagram illustrating a procedure for establishing and confirming a lung tumor model after injecting tumor cells emitting luciferase-RFP fluorescence into nude mice. FIG.
FIG. 23 is a photograph confirmed by fluorescence imaging equipment (IVIS in vivo imaging system) and lung tissue staining after tumor cell injection into a lung tumor model mouse.
24 is a photograph observing whether the generation of fluorescence lung tumor by the administration of the stem cell-nano anticancer complex (hMSC-CD90-mwCNT-DOX) prepared according to an embodiment of the present invention with fluorescence imaging equipment.
25 is a graph analyzing the intensity of fluorescence observed after administration of the stem cell-nano anticancer complex (hMSC-CD90-mwCNT-DOX) prepared according to one embodiment of the present invention.
Figure 26 is a photograph observed by H & E histochemical staining that the production of lung tumors was inhibited by administration of the stem cell-nano anticancer complex (hMSC-CD90-mwCNT-DOX) prepared according to an embodiment of the present invention.
FIG. 27 is a diagram schematically illustrating a process of applying a stem cell-nano anticancer complex (hMSC-CD90-mwCNT-DOX, hMSC-CD90-Au-DOX) selectively targeted to a specific cancer.

Definition of Terms:

As used herein, the term "mesenchymal stem cells (MSCs)" refers to adult mesenchymal stem cells (MSCs) among adult stem cells and is derived from bone marrow, cord blood, or adipose cells. It is characterized by having differentiation ability.

As used herein, the term "carbon nanotube" (CNT) is a carbon allotrope made up of a large amount of carbon present on the earth, a material in which one carbon is combined with another carbon atom in a hexagonal honeycomb pattern to form a tube. It means the material of the extremely small area with the diameter of the tube in the order of nanometer (nm = 1 billionth of a meter).

The carbon nanotubes are known to be perfect new materials having excellent mechanical properties, electrical selectivity, excellent field emission characteristics, high-efficiency hydrogen storage medium properties, and few defects among existing materials, and are manufactured by highly synthetic technology. Synthesis methods include electric discharge, pyrolysis, laser deposition, plasma chemical vapor deposition, thermochemical vapor deposition, electrolysis, flame synthesis, and the like.

As used herein, "Gold nanoparticles (AuNP)" is the particle size of the gold particles as well as a perfect sphere of about 1 ^-9 m to be in the nanometer scale is irregular in shape, and in accordance with the respective shapes and sizes, Different states and different colors. Depending on the states, the color is determined by how much of the region reflects and absorbs the wavelength. Through this, the energy gap can be inferred, and the larger the size, the shorter the wavelength of the color can be attached to the anticancer agent to use the particles as a drug carrier, or by attaching a specific antibody can be used to detect the antigen on the cell surface. In addition, it can be used as a therapeutic agent for rheumatoid arthritis, and is a next generation new substance that can be used in various fields as well as the medical part.

As used herein, the term "nano-cancer complex" is intended to control the release and absorption of an anticancer agent, or to target and deliver an anticancer agent to a specific part of the body, and to maximize the efficacy while reducing the side effects of the anticancer agent. It is to control the anticancer agent in the target site to effectively stay for a certain time. It means an anticancer drug delivery system using nanotechnology.

As used herein, the term "carbon nanotube (CNT) or class (Au) nanoparticles loaded with anticancer agent" means the introduction of a functional group such as a carboxyl group (-COOH) to carbon nanotubes or gold nanoparticles. And anticancer nanoparticles having an anticancer agent such as doxorubicin or paclitaxel or an anticancer agent such as trastuzumab, adalimumab, and infliximab attached to a gold nanoparticle surface. The functional group introduction of carbon nanotubes can be performed by acid treatment, and since the gold particles themselves have no functional groups, they are coated with a polyester-based biocompatible polymer such as PEG or PLGA substituted with a carboxyl group to stabilize electrostatically. It can be prepared by combining an anticancer agent or an antibody such as doxorubicin with (-NH ₂ ).

As used herein, the term "functional fragment of an antibody" refers to a fragment of an antibody that retains the ability of antigen binding to retain the function of the antigen binding site of the antibody. Functional fragments of these antibodies include protease fragments such as Fab, Fab 'and F (ab') 2 and Fv, scFv, diabody, triabody, and sdAb, which are produced by cleaving the antibody with proteases such as papain or pepsin. Also included are recombinant antibody fragments produced by genetic recombination.

As used herein, the term "Fab" refers to a fragment generated by cleaving an antibody molecule with papain, a protease, as an antigen-binding antibody fragment, which is the amount of two peptides, VH-CH1 and VL-CL. In other words, other fragments produced by papain are referred to as fragment crystalisable (FC).

As used herein, the term “F (ab ′) ₂ ” refers to a fragment containing an antigen binding site among fragments generated by cleaving an antibody with pepsin, a protease, and forms a tetramer in which two Fabs are linked by disulfide bonds. Indicates. Another fragment produced by pepsin is called pFc '.

The term "Fab '", as used herein, is an antibody fragment having a structure similar to that of Fab, resulting from the reduction of F (ab') 2, with the length of the heavy chain portion slightly longer than that of Fab.

As used herein, the term "scFv" refers to a recombinant chain fragment prepared by using a linker in a variable chain (VH and VL) in the Fab of the antibody as a single chain fragment variable.

The term "sdAb (single doamain antibody)" as used herein is referred to as a nanobody and is an antibody fragment consisting of a single variable region fragment of an antibody. Although sdAbs mainly derived from heavy chains are used, single variable region fragments derived from light chains have also been reported to have specific binding to antigens.

As used herein, the term "V _H H" is a variable region fragment of the heavy chain of IgG consisting only of dimers of heavy chains found in camels, the smallest (~ 15 kD) of antibody fragments that specifically bind to the antigen. and it has, Nanobody by four Ablynix ^?? It was developed under the trade name.

As used herein, the term "Fv (fragment variable)" is a dimeric antibody fragment consisting of only the variable and heavy chains of the antibody (VH and VL), the size of the sdAb and Fab (about 25 kD) Antibodies are produced by proteolytic hydrolysis under specific conditions or by inserting genes encoding VH and VL into one expression vector.

As used herein, the term "diabody" refers to a divalent bispecific that is made to shorten the linker length between VH and VL of the scFv (5 aa) so that the two scFvs form dimers with each other. Recombinant antibody fragments with bispesific are known to have higher antigen specificity than conventional scFv.

As used herein, the term "triabody" refers to a trivalent recombinant antibody fragment prepared so that three scFvs form trimers with each other.

As used herein, the term "antibody mimetics" is a single chain-based protein capable of specifically binding to an antigen, similar to an antibody, introducing random mutations into the antigen recognition site of the underlying scaffold protein. It is then screened through panning. Such antibody analogues include apirin (affilins; Ebersbach, H. et al . J. Mol. Biol ., 372: 172-185, 2007), affimers; Johnson, A. et al . Anal. Chem . 84 (15): 6553-6560, 2012), apitin (affitins; Krehenbrink, M. et al ., J. Mol. Biol. , 383: 1058-1068, 2008), anticalins (Skerra, A. et. al ., FEBS J. , 275: 2677-2683, 2008), avimers; Silverman, J. et al . Nat. Biotechnol ., 23: 1556-1561, 2005), DARPin (Stumpp, MT et al. Drug Discov. Today 13 (15-16): 695-701, 2008), finomers (Fynomers, Grabulovski, D. et al., J. Biol. Chem. 282 (5): 3196-3204, 2007), Monobodies (Koide, A. et al ., Methods Mol. Biol ., 352: 95-109, 2007), VLR (variable lymphocyte receptor; Boehm, T. et al., Annu. Rev. Immunol. 30: 203-220, 2012), repebodies, Lee, S.-C. et al ., Proc. Natl. Acad. Sci. USA 109 (9): 3299-3304, 2012).

Detailed description of the invention:

According to an aspect of the present invention, a stem cell-nano anticancer complex, in which carbon nanotubes (CNT) or gold (Au) nanoparticles loaded with an anticancer agent on a stem cell surface, are provided.

In the stem cell-nano anticancer complex, the carbon nanotubes may be multi-walled carbon nanotubes and the multi-walled carbon nanotubes may have a diameter of 5 to 50 nm.

In the stem cell-nano anticancer complex, the carbon nanotube or gold nanoparticle may be attached to the stem cell by attaching an antibody specific to a stem cell labeling protein, a functional fragment or antibody mimetics of the antibody. And the functional fragment of the antibody may be Fab, F (ab ') 2, Fab', scFv, Fv, VHH (variable domain of camelid heavy chain), sdAb, diabody or triabody and the antibody analogues are Affibody, Affilin, Affitin , Anticalin, Avimer, DARPin, Fynomer, monobody, variable lymphocyte receptor (VLR) or repebody and the stem cell marker protein may be CD90, CD73 or CD105.

In the stem cell-nano anticancer complex, the complex may have a weight ratio of carbon nanotubes and an anticancer agent in a ratio of 1: 1 to 1: 3, and the anticancer agent is doxorubicin, paclitaxel, ABT737, 5-fluorouracil, BCNU, CCNU, 6-mercaptopurine, nitrogen mustard, cyclophosphamide, vincristine, vinblastine, cisplatin, mesotrexate, cytarabine thiothepa, busulfan or procarbazine and the stem cells are fat stem cells, Cord blood stem cells, dedifferentiated stem cells, or mesenchymal stem cells (MSC).

In the stem cell-nano anticancer complex, the gold nanoparticles may be coated with a polymer material having a carboxyl group, and the polymer material having a carboxyl group may be a carboxylated PEG (polyethylene glycol), hyaluronic acid, or PHA ( polyhydroxyalkanoates), PLGA {poly (lactic-co-glycolic acid)}, PLA {poly (lactic acid)} or PGA {poly (glycolic acid)}.

According to another aspect of the invention, there is provided an anticancer pharmaceutical composition containing the stem cell-nano anticancer complex as an active ingredient.

According to another aspect of the present invention, there is provided a method for treating cancer, comprising administering the therapeutically effective amount of a stem cell-nano anticancer complex to a subject with cancer.

In the anticancer pharmaceutical composition of the present invention, the pharmaceutical composition of the present invention may include a pharmaceutically acceptable carrier. The composition comprising a pharmaceutically acceptable carrier may be a variety of oral or parenteral formulations, but is preferably a parenteral formulation. When formulated, diluents or excipients such as fillers, extenders, binders, wetting agents, disintegrating agents, and surfactants are usually used. Solid preparations for oral administration include tablets, pills, powders, granules, capsules and the like, and such solid preparations contain at least one excipient such as starch, calcium carbonate, sucrose or lactose, gelatin, or the like in one or more compounds. Mix is prepared. In addition to simple excipients, lubricants such as magnesium stearate, talc and the like can also be used. Liquid preparations for oral administration include suspensions, liquid solutions, emulsions, and syrups, and various excipients such as wetting agents, sweeteners, fragrances, and preservatives, in addition to commonly used simple diluents such as water and liquid paraffin, may be included. have. Formulations for parenteral administration include sterile aqueous solutions, non-aqueous solvents, suspensions, emulsions, lyophilized preparations, suppositories. As the non-aqueous solvent and the suspension solvent, propylene glycol, polyethylene glycol, vegetable oil such as olive oil, injectable ester such as ethyl oleate, and the like can be used. As the base of the suppository, witepsol, macrogol, tween 61, cacao butter, laurin butter, glycerogelatin and the like can be used.

The anticancer pharmaceutical composition is selected from the group consisting of tablets, pills, powders, granules, capsules, suspensions, solutions, emulsions, syrups, sterile aqueous solutions, non-aqueous solutions, suspensions, emulsions, lyophilized preparations and suppositories. It can have any one formulation.

The anticancer pharmaceutical composition of the present invention may be administered orally or parenterally, when administered parenterally, it is administered through various routes such as intravenous injection, intranasal inhalation, intramuscular administration, intraperitoneal administration, and transdermal absorption. It is possible.

The composition of the present invention is administered in a pharmaceutically effective amount.

As used herein, the term “pharmaceutically effective amount” means an amount sufficient to treat a disease at a reasonable benefit / risk ratio applicable to medical treatment, with an effective dose level of the type and severity of the subject, age, sex, and anticancer agent. Activity, sensitivity to anticancer agents, time of administration, route of administration and rate of excretion, duration of treatment, factors including concurrently used anticancer agents, and other factors well known in the medical art. The pharmaceutical composition of the present invention may be administered at a dose of 0.1 mg / kg to 1 g / kg, more preferably at a dose of 1 mg / kg to 500 mg / kg. On the other hand, the dosage may be appropriately adjusted according to the age, sex and condition of the patient.

The anticancer pharmaceutical composition of the present invention may be administered as a separate treatment or in combination with other anticancer agents, and may be administered sequentially or simultaneously with other conventional anticancer agents. And single or multiple administrations. Taking all of the above factors into consideration, it is important to administer an amount that can obtain the maximum effect in a minimum amount without side effects, and can be easily determined by those skilled in the art.

In the case of conventional nano-cancer drugs, the biodegradable polymers used in the formulation have been easily dissociated from the nano-materials at an acidic pH and blood conditions, so that there is a limit to the delivery of the anti-cancer agent to the target site, and conventional silica, magnetic particles, and carbon-based nano Non-degradable nanoparticles, such as particles, have difficulties to be resolved, such as lack of efficacy in anti-toxic anticancer doses and accumulation in reticular endothelial system (RES) organs. In order to maximize the efficacy of these conventional anticancer drugs, studies on carbon nanotube-based anticancer drugs continue. Carbon nanotubes (carbon nanotubes, CNTs) are composed of carbon-based materials, such as graphite, carbon tube, fullerene, and graphene. , Diamond, etc. have been applied in various biomedical fields including imaging, cancer treatment, etc. due to their mechanical, visual, and chemical properties (Bae, S., et al., Nat. Nanotechnol. 5, 574, 2010). . Recently, carbon nanotubes have been widely used in anti-cancer drug carriers, medical imaging agents, DNA conjugates, biosensors, biochips, etc. in the bio field because of their weight, concentration, surface area, and easy bonding with biomaterials. (Yang, W., et al., Nanotechnol. , 18, 412-421, 2007).

In addition, gold (Au) accounts for less than 1% of the constituents of the earth's crust, making it well known as one of the first metals used by mankind, and has long been used for gold coins, decorative, and dental care. In addition, in recent years, in the electronic, satellite, nuclear power industry, such as the use of a variety of alloys, such as micro-wires, plating, electrical contacts, and is used in a variety of alloy forms, it is made of nanoparticles through a variety of methods. Methods of preparing gold nanoparticles include chemical synthesis, mechanical production, and electrical production. In the mechanical manufacturing method of grinding using mechanical force, it is difficult to synthesize particles of high purity due to incorporation of impurities in the process, and it is impossible to form uniform particles of nano size. As a practical method, a laser ablation method, an oven beam method, and a high energy ball milling method are used. The laser ablation method applies a laser beam to a raw material under vacuum. Nanoparticles are produced by condensing vapors of atoms or molecules generated and using lasers that are relatively expensive and have low thermal efficiency.Therefore, the production cost is too high compared to the production amount. Also, condensation of vapors generated by melting materials with low break points under vacuum Oven beam method for making nanoparticles and high-energy ball milling method for making nanoparticles by mechanically grinding nanoparticles requires a high level of technology, a very difficult manufacturing process, and expensive manufacturing equipment. In addition, the electrical manufacturing method by the electrolysis has a disadvantage that the production time is long, the concentration is low, the efficiency is low. There are two methods of chemical synthesis: gas phase method and liquid phase method (colloidal method). The gas phase method using plasma or gas evaporation method requires expensive equipment, and the process is complicated and the efficiency is low. The liquid phase method which can synthesize | combine is mainly used. The method for preparing gold nanoparticles by the liquid phase method may include dissolving a compound in a liquid phase and then preparing gold nanoparticles in a hydrosol form using a reducing agent or a surfactant. Recently, research on the chloroauric acid (HAuCl ₄₎ the salt conditions of producing the gold nanoparticles from the liquid phase reduction method for synthesizing the inorganic compound in the colloidal state with a reducing agent, and to this load cancer targeted ability of a cancer cell enhanced anticancer complex Development is underway.

The present inventors have made efforts to overcome the target limitations of the conventional nano-cancer drugs and maximize the efficacy of the anti-cancer drugs. As a result, the carbon nanotubes (CNT) and gold (Au) on the surface of the mesenchymal stem cells (MSCs) having excellent targeting ability to cancer cells ) A stem cell-nano anticancer complex having cancer targeting and apoptosis of stem cells loaded with an anticancer agent having proven anticancer effect on nanoparticles was developed (FIG. 1).

Hereinafter, the invention will be described in detail by way of examples. However, the present invention is not limited to the embodiments disclosed below, but can be implemented in various different forms, the following examples are intended to complete the disclosure of the present invention, to those skilled in the art the scope of the invention It is provided to fully inform you.

Example 1 Preparation of Carbon Nanotubes (mwCNT)

According to an embodiment of the present invention was prepared a carbon nanotube to be used in the production of a stem cell-nano anticancer complex loaded with a nano anticancer agent on the surface of mesenchymal stem cells (MSC) very good target cancer cells.

Specifically, the carbon nanotubes are easily aggregated by van der Waals attraction and difficult to disperse, so that the carbon nanotubes oxidize carbon atoms at the ends and defect sites of the carbon nanotubes. Acid was used. By oxidizing a functional group containing oxygen on the surface of the carbon nanotube using an acid solvent, a functional group such as a carboxylic group can be introduced. As described above, the carboxyl group was introduced to the surface to prepare surface functionalized carbon nanotubes as follows. Method for introducing a carboxyl group on the surface of the multi-walled carbon nanotubes (a) incorporating carbon nanotubes in a strong acid solvent, chemically oxidizing functional groups containing oxygen on the surface of the carbon nanotubes, and ( b) by ultrasonication in the acid solvent. Multi-wall canbon nanotubes (MWCNTs) contain 20 mg of SES research products (lot NT-0140, catalog # 900-1260, Inc USA) with a diameter of 10-30 nm in H ₂ SO ₄ (98 %) 9 ml and ₃ ml HNO ₃ (65%) were mixed in a volume ratio of 3: 1, and then sonicated for 30 minutes. At this time, the ultrasonic treatment was performed for 80 to 120 minutes in the 20-25 KHz frequency range. The frequency range may be 20-22 KHz, in which case it may be sonicated for 90 minutes to 110 minutes. By this process, the aggregated nanotube structure was cut into a short bundle structure, and the shockwave generated during the ultrasonic treatment made the suspended solid particles more dispersed. Thereafter, the solution was heated at 50 ° C. for 24 hours while stirring at a speed of 300 rpm using a magnetic bar. The reaction with the acid solvent and the sonication step were repeated once. The chemically functionalized MWCNT (MWCNT-COOH) through the step was filtered using a filter membrane (Millipore, lot: ROBA95509) of 10 μm diameter, the filter membrane at 60 ℃ for 16-20 hours Dry in vacuo. The chemically functionalized MWCNT-COOH was then scraped off the filter membrane using a medical scrap of stainless steel. Through the experimental step, a carboxyl residue (-COOH) was generated at a defect site of the surface of the nanotube. Variations that carboxylate the defects of carbon nanotubes increase the solubility of the carbon nanotubes in water or organic solvents.

Example 2: Preparation of Gold Nanoparticles (AuNP)

According to one embodiment of the present invention, gold (Au) nanoparticles were prepared to be used for preparing a stem cell-nano anticancer complex in which a nano anticancer agent was loaded on a surface of a mesenchymal stem cell (MSC) having excellent targeting ability to cancer cells.

Specifically, the synthesis of gold nanoparticles was synthesized in the colloidal state of the inorganic compound in the gold chloride (HAuCl ₄ ) salt state using a reducing agent (using the Turkevich method). 2.2 ml of 300 ml of sodium citrate from Sigma Aldrich (catalog # S4614) was heated to 100 ° C, and then 2 ml of 25 mM Sigma Aldrich (catalog # 520918) chloride was added to reduce gold nanoparticles at 300 RPM. I was. The solution during the reduction reaction is gray and red in a transparent color, the reaction proceeds within 15 minutes, and the synthesized gold nanoparticles are cooled at room temperature for 30 minutes or more and stabilized. All of the above reactions were carried out using tertiary distilled water as a solvent. The synthesized gold nanoparticles are in equilibrium by citrate ions, but lose their equilibrium by salt or lyophilization, and are easily brought about by van der Waals attraction between particles. There is a characteristic of flocculation. To compensate for this drawback, 1 mg / mL of polymer (α-Mercapto-ω-carboxy-PEG) is reacted with 2 mg / mL of gold nanoparticles for 24 hours to form a self assembled monolayer on the surface. As a result, the steric stability was increased, and the electrostatic stability due to the carboxylate negative charge of the polymer was also improved. The prepared polymer-coated carboxylated gold nanoparticles (AuNP-COOH) were separated from the solvent at a rate of 16000 g using a centrifugal separator and resuspended using tertiary distilled water and then suspended.

Example 3: Connection of EDC Linker

According to an embodiment of the present invention, the carbon nanotubes prepared in Example 1 and the gold nanoparticles prepared in Example 2 were combined with an EDC linker for stability of protein binding.

Specifically, the reaction of binding the EDC linker to the carbon nanotubes (MWCNT-COOH) and the gold nanoparticles (AuNP-COOH) was carried out in a weakly acidic 2-morpholinoethanesulfonic acid (MES) and low moisture content ≧ 99%, sigma-aldrich CAT: M3671) was used to adjust the pH of the solution. First, 10 mg AuNP-COOH and 3.2 mg MWCNT-COOH, respectively, were placed in 1.6 ml MES buffer (50 mM, pH 5.5), followed by a tip sonicator (company: Misonix sonicators, Product: sonicator) 4000) for 5 minutes with a cycle of 3 seconds on / 3 seconds off. Thereafter, a solution of 1.6 ml NHS (400 mM) (N-hydroxysuccinimide, Cas: 06066-82-6) mixed with MES buffer (50 mM, pH 5.5) was added to the ultrasonically ground solution, followed by 30 minutes. While mixing using Rocker. Then 10 mL EDC solution (20 mM) (N- (3-Dimethylaminopropyl) -N-ethylcarbodiimide hydrochloride (Sigma, Lot No .: 040M17411V)) was added to the sonication solution and mixed with Rocker for 30 minutes to give EDC Linker-linked carbon nanotubes (EDC-MWCNT-COOH) and gold nanoparticles (EDC-AuNP-COOH) were prepared, respectively.

The mixed solution was placed in 4 Centricon YM-50 filter tubes (Amicon ultra-15, 50K device-50000 NMWL, TM millpore, USA) and centrifuged at 2,000 rpm, followed by 3 times with MES buffer (50 mM) or It was washed further, where centrifugation was performed for 20 minutes at a time. And 5 mg of the MWCNT-COOH 5 ml PBS (phosphate buffered saline) 5 ml using a tip sonicator under conditions of 3 seconds on / 3 seconds off was further performed for 5 minutes, this state is the anticancer agent It was used as a control for the loaded carbon nanotube-based anticancer agent.

Example 4 Preparation of Carbon Nanotube-Based Anticancer Agent

4-1: Preparation of mwCNT loaded with anticancer agent by covalent bond

Carbon nanotube-based anticancer agent according to an embodiment of the present invention has an increased binding rate of the anticancer agent compared to the conventional anticancer agent using a covalent bond. In order to increase the binding rate of the anticancer agent compared to the prior art, the pH at the EDC linker binding and anticancer agent binding was adjusted. PH 5.5 was chosen to induce maximum binding of the EDC linker in the range of pH 4-6, which is the condition that EDC linker attaches best. Even though it was adjusted to a pH range that can inhibit the hydrolysis of EDC. The two changes in pH (pH 5.5 and 6) induced strong covalent bonds by maximizing the loading of the anticancer agent while maintaining stable EDC linker binding.

Thereafter, the prepared EDC-mwCNT solution was bound to doxorubicin (Doxorubicin, DOX, Sigma-aldrich, Cat # D1515) which is a cancer cell fission inhibiting anticancer agent. At this time, the EDC-mwCNT and the anticancer agent were mixed at a concentration ratio of 1: 1, and stirred at 4 ° C. for 14-18 hours in a platform shaker, and the EDC-mwCNT solution loaded with the anticancer agent was senticon YM- Centrifugation was performed at 2,000 rpm using a 50 filter tube and residual doxorubicin that failed to bind was removed by removing the supernatant. Then, mwCNT (mwCNT-DOX) loaded with doxorubicin was dissolved in 5 ml of PBS and used in the following experiment.

4-2: Preparation of AuNP with Anticancer Agent by Covalent Bond

Gold nanoparticle-based anticancer agent according to an embodiment of the present invention, the binding using the EDC / NHS cross-linking chemicals. MES buffer, which is easy to stabilize pH, was used as a solvent to induce stable coupling reaction between gold nanoparticles and anticancer agents, and NHS-ester derivatives were formed on the surface of gold nanoparticles by proceeding the reaction at pH6 to reduce the hydrolysis efficiency of EDC. do.

Specifically, the AuNP-NHS ester solution prepared above was combined with doxorubicin (Doxorubicin, DOX, Sigma-aldrich, Cat # D1515), a cancer cell fission inhibiting anticancer agent. At this time, the AuNP-NHS ester of 4 nM concentration and the anticancer agent of 0.17 mM concentration were mixed and stirred at 4 ° C. for 20 to 24 hours using a magnetic stirrer, and the AuNP-NHS ester solution loaded with the anticancer agent was Centrifugation was performed at 10000 g using a centrifuge and residual doxorubicin that failed to bind was removed by removing the supernatant. Then, AuNP (AuNP-DOX) loaded with doxorubicin was dissolved in 1 ml of PBS and used for the following experiment.

Example 5: MSC-Nano Anticancer Binding

According to an embodiment of the present invention, the antibody that specifically recognizes CD90, a labeling protein, is shown on the surface of MSCs that show non-target and non-toxicity to surrounding normal cells but have traceability and killing ability in non-pulmonary and small lung cancer lines. After reacting with the EDC-mwCNT and AuNP-NHS ester solution prepared in Example 3 at a concentration of 20 μg / ml for 30 minutes, doxorubicin was combined and stirred at 4 ° C. for 14-18 hours in a platform shaker. I was. Subsequently, the anticancer loaded EDC-mwCNT and AuNP-NHS ester solutions were centrifuged at 4,000 rpm using a Centricon YM-50 filter tube to remove the remaining doxorubicin and antibodies that failed to bind by removing the supernatant. . After the CD90 antibody-doxorubicin-mwCNT complex (CD90-mwCNT-DOX) and CD90 antibody-doxorubicin-AuNP complex (CD90-AuNP-DOX) prepared in Example 3 were reacted with stem cells at a concentration of 1 μg / ml, Remove unbound CD90-mwCNT-DOX and CD90-AuNP-DOX and use a fluorescent microplate reader (VICTOR X3, PerkinElmer) to bind the stem cell-nano anticancer complex (hMSC-CD90-mwCNT-DOX, hMSC) The DOX fluorescence wavelength of -CD90-AuNP-DOX) was measured. For hMSC-CD90-mwCNT-DOX, a stem cell-nano anticancer complex (hMSC-CD90-mwCNT-DOX) equipped with 72 ng / ml of doxorubicin nano anticancer agent per 1 × 10 ⁵ stem cell was prepared, using a confocal fluorescence microscope. It was confirmed that doxorubicin binding mwCNT and AuNP is properly attached to the stem cell surface (Fig. 2).

Example 6: Confirmation of optimization of nanoanticancer binding to stem cells

Anticancer agent per cell of the stem cell-nano anticancer complex (hMSC-CD90-mwCNT-DOX, hMSC-CD73-mwCNT-DOX) bound using an antibody binding to the stem cell marker protein CD90 or CD73 according to an embodiment of the present invention The changes of anticancer drug load per cell according to the degree of loading and CD antibody, the anticancer drug persistence with time of hMSC-CD90-mwCNT-DOX, and the change of cell survival rate of stem cells after nano anticancer drug binding over time were confirmed.

Specifically, in order to check the degree of loading of doxorubicin according to the concentration of the marker protein and nano anticancer agent of MSC, CD90-mwCNT-DOX was treated with MSC for 2 hours by concentration (1, 2 μg / ml) and washed 3 times with 1X PBS. Afterwards, the amount of bound nano doxorubicin anticancer agent was measured using a fluorescent microplate reader (FIG. 3). In addition, MSC-treated stem cell-nano anticancer complexes (CD90-mwCNT-DOX, CD73-mwCNT-DOX, CD90-CD73-mwCNT-DOX) bound to each CD antibody were treated for 2 hours at a concentration of 1 μg / ml and 1X PBS. After washing with fluorescence wavelength of the nano doxorubicin anticancer agent bound to MSC using a fluorescent microplate reader was measured the change in the amount of doxorubicin anticancer agent bound per cell according to the binding CD antibody (Fig. 4). In addition, after binding mwCNT-CD90-DOX to MSC, how much nano-cancer drug bound to MSC is maintained, and after 24, 48, 72, 144 hours, nano-doxorubicin anti-cancer maintenance was measured using flow cytometry (FACS). And analyzed. MSC 5 × 10 ³ cells were seeded in 96 well plates and 18 hours of incubation followed by mwCNT-CD90-DOX concentration (1, 2, 5 and 10 μg / ml) and hourly (24, 48, 72 and 144). Hours) MTT reagent (3- (4,5-dimethylthiazol-2-yl) -2,5-diphenyltetrazolium bromide, 3- (4,5-Dimethylthiazol-2-) at a concentration of 1 mg / ml after treatment yl) -2,5-diphenyltetrazolium bromide) was added to 100 µl of each well, and further incubated at 37 ° C for 2 hours. Subsequently, 100 μl of DMSO solution was added per well, and then the absorbance was measured at 570 nm using a microplate reader (UVM340, ASYS) to confirm the survival rate of MSC.

As a result, when the two CD90-CD73 antibodies were combined together, it was confirmed that the binding of the nanoanticancer agent was much higher than when using the CD73 and CD90 antibodies, respectively. The nanoanticancer agent was added up to 96 hours after hMSC-CD90-mwCNT-DOX binding. It appeared to remain high (FIG. 5). In addition, binding of mwCNT-CD90-DOX to 10 μg / ml was not toxic to MSC itself, and it was confirmed that MSC survival was maintained at 60% or more by 144 hours (FIG. 6).

Experimental Example 1 Verification of MSC Toxicity According to Labeling Proteins of Stem Cell-Nano-cancer Complex

According to one embodiment of the present invention, the labeling protein antibodies that can be bound to stem cells in the preparation of the stem cell-nano anticancer complex include CD90, CD73, and CD105. Stem cell-nano anticancer complexes (MSC-CD90-mwCNT-DOX and MSC-CD73-mwCNT-DOX) prepared to bind to labeled proteins differently for short-term (72 hours) and long-term (240 hours) lung cancer cells (H1975) After treatment, the killing of the stem cell-nano anticancer complex was analyzed.

Specifically, the lung cancer cell line (H1975) is seeded in a 100π culture plate at a rate of 4 × 10 ⁵ cells per well, and then in DMEM (Dulbeco's Modified Eagle's Medium) medium containing 10% fetal bovine serum (FBS). Incubated. Stem cells prepared to be combined different from the labeled protein - a short period of nano-cancer drug conjugate (MSC-CD90-mwCNT-DOX and MSC-CD73-mwCNT-DOX) at a rate of 4 × 10 ⁵ cells (72 hours) and long term ( 240 hours) after treatment with lung cancer cells (H1975), after the stem cell specific markers (CD90, CD73) and fluorescent cell death markers (Annexin V) staining, MSC death and other marker proteins were analyzed using FACS.

As a result, the MSC-CD90-mwCNT-DOX test group showed no MSC self-toxicity compared to the MSC-CD73-mwCNT-DOX test group, and the MSC-CD73-mwCNT-DOX test group showed toxicity due to ROS increase during long-term treatment. Stem cells themselves were confirmed to die, so the stem cell nano-anticancer complex of the MSC-CD90-mwCNT-DOX experimental group appeared to be more suitable for the experiment (FIG. 7).

Experimental Example 2 Analysis of Changes in Calcium Signaling in MSC Cells According to Labeling Proteins of Stem Cell-Nano-Cell Complexes

Stem cell-nanoanticancer complexes prepared according to an embodiment of the present invention (MSC-CD90-mwCNT-DOX and MSC-CD73-mwCNT-DOX) were reacted with lung cancer cells (H1975) and then the stem cell-nano anticancer complexes MSC intracellular calcium signaling was analyzed.

Specifically, the lung cancer cells (H1975) and the stem cell-nano anticancer complexes (MSC-CD90-mwCNT-DOX and MSC-CD73-mwCNT-DOX) were co-cultured on the coverslip for 48 hours at a ratio of 4 × 10 ⁵ cells. 0.05% Pluronic F-127 containing 4 μM of Fura-2 was added to physiological saline and reacted together at dark room temperature for 15 minutes. Subsequently, MSC cells of the stem cell-nano anticancer complexes (MSC-CD90-mwCNT-DOX and MSC-CD73-mwCNT-DOX) according to the labeled protein antibody at the excitation / release 340/510 nm fluorescence wavelength using a fluorescence microscope Changes in calcium signaling were identified and analyzed using MetaFluor system.

As a result, the MSC calcium signaling change was highest in the MSC-CD73-mwCNT-DOX experimental group compared to the MSC-CD90-mwCNT-DOX experimental group (FIG. 8), and MSC cell damage was detected in the MSC-CD73-mwCNT-DOX experimental group. ) Was found to occur most frequently (FIG. 9).

Experimental Example 3: Analysis of cancer cell target ability and function of stem cell-nano anticancer complex

Stem cell-nano anticancer complex functionalities were confirmed through analysis of cancer cell target ability change after preparation of the stem cell-nano anticancer complex (hMSC-CD90-mwCNT-DOX) prepared according to one embodiment of the present invention.

Specifically, the experimental cell lines were NHFB (human fibroblast, normal cell line), A549 (non-small cell lung cancer line), MDA-MB-231 (breast cancer cell line) and U87MG (glioblastoma). Migration analysis for the screening was carried out in a 24-well transwell using a polycarbonate membrane having 8 μm porosity. The MSCs were placed in the upper chamber of the Transwell appendage at a density of 5 × 10 ⁴ cells / ml 200 μl medium ( α -minimum essential medium + 0.5% fetal calf serum). The lower chamber contained 500 μl of medium incubating NHFB (human fibroblast, normal cell line), A549 (non-small cell lung carcinoma), MDA-MB-231 (breast cancer cell line) and U87MG (neuroglioblastoma). After incubation for 5 hours at 37 ° C. under 5% CO ₂ , the post-non-mobile cells of the upper surface of the membrane were removed and washed with phosphate buffered saline. The membrane was then fixed in 100% methanol for 1 minute and stained with 1% DAPI (4 ', 6-Diamidino-2-Phenylindole, Dihydrochloride), a nuclear staining reagent, for 30 minutes. The mobile cell number was determined by counting ten random portions per well under a microscope at x 200 magnification and for comparison, the stem cell-nanoanticancer complex (MSC-CD90-CD73-CNT), in which CD90 and CD73 antibodies were bound to stem cells together Stem cells uptake of -DOX) and nanocancer drugs were also analyzed.

As a result, even after preparation of the stem cell-nano anticancer complex (hMSC-CD90-mwCNT-DOX), cancer targeting ability was found to be almost similar to that of pure MSC (FIG. 10).

Experimental Example 4: Comparison of nano chemotherapy efficiency and lung cancer target functionalities between nano chemotherapy loading group and stem cell-nano anticancer complex in stem cells

Doxorubicin anticancer loading efficiency and lung cancer cell targeting capacity change of the stem cell-nanoanticancer complex prepared according to an embodiment of the present invention were analyzed by comparing with the nanoanticancer loading test group in stem cells.

Specifically, lung cancer cells (H1975) and stem cell-nano anticancer complexes (MSC-CD90-mwCNT-DOX and MSC-CD73-mwCNT-DOX) were co-cultured on the coverslip for 48 hours at a rate of 4 × 10 ⁵ cells. Next, 0.05% Pluronic F-127 containing 4 μM of Fura-2 was added to physiological saline and reacted together at a dark room temperature for 15 minutes. Subsequently, the stem cell-nano anticancer complex (MSC-CD90-mwCNT-DOX and MSC-CD73-mwCNT-) according to the labeling protein antibody at excitation / emission 340/510 nm fluorescence wavelength using a fluorescence microscope The changes in intracellular calcium signaling in MSC cells of DOX) were analyzed and analyzed using MetaFluor system.

As a result, the stem cell-nano anticancer complex (hMSC-CD90-mwCNT-DOX) showed better doxorubicin anticancer drug loading efficiency (Figs. 11 and 12) and lung cancer targeting ability when compared with the nano-cancer drug loading test group in stem cells. It was confirmed (Fig. 13).

Experimental Example 5: Verification of apoptosis of MSC after preparation of stem cell-nano anticancer complex

According to one embodiment of the present invention, after the production of the optimized stem cell-nano anticancer complex, MSC stem cell self-toxicity was analyzed by comparing with the stem cell group loaded with the nanoanticancer agent.

Specifically, the MSC 5 × 10 ⁵ cells were absorbed or conjugated with a nano-cancer agent at a concentration of 1 μg / ml for 2 hours, and then cultured with lung cancer cells for 24 hours after replacing the medium. The degree of death was analyzed using FACS after staining the stem cell specific marker (CD90) and fluorescent cell death marker (Annexin V).

As a result, it was confirmed that MSC toxicity was lower in the stem cell-nano anticancer complex experimental group compared to the nano-cancer drug loading experimental group in the stem cells (FIG. 14).

Experimental Example 6: Verification of amplified cancer cell killing ability of stem cell-nano anticancer complex

In accordance with an embodiment of the present invention, the stem cell-nano anticancer complex optimized in functionality was injected into cancer cells and analyzed for killing ability.

Specifically, the lung cancer cell line (H1975) in a 100π culture plate to compare whether the stem cell-nano anticancer complex of the present invention amplify cancer cell death compared to the free MSC (BM-MSC) and the nano-cancer drug loading experimental group in stem cells After seeding at a rate of 5 × 10 ⁵ cells per well, the cells were cultured in DMEM (Dulbeco's Modified Eagle's Medium) medium containing 10% fetal bovine serum (FBS). At this time, the incubator was kept in a humid state at a temperature of 37 ℃ under 5% CO ₂ condition. Function optimized stem cell-nano anticancer complex, free MSC (BM-MSC) and nano-cancer drug loading test group in stem cells were observed up to 240 hours after treatment with 5 × 10 ⁵ cells. Lung cancer cells (CD54) and stem cell specific markers (CD90) and fluorescent cell death markers (Annexin V) were stained and analyzed using flow cytometry (FACS).

As a result, the stem cell-nano anticancer complex showed high lung cancer cell killing ability up to a long time (240 hours) compared to the free MSC (BM-MSC) and the nano-cancer drug loading test group in stem cells (FIGS. 15 and 16). It was observed that death increased greatly up to 240 hours after the time (FIG. 17).

Experimental Example 7 Analysis of Calcium Signaling Between Stem Cells Loading Nanocancer Drugs and Cancer Cells of Stem Cell-Nanocancer Complexes

According to an embodiment of the present invention, after treating the stem cell-nano anticancer complex optimized in functionality to cancer cells, the intracellular calcium signaling changes of lung cancer cells (H1975) were compared and analyzed in comparison with the nano-cancer drug loading test group in the stem cells. .

Specifically, lung cancer cells (H1975, 4 × 10 ⁵ ) were treated to the stem cell-nano anticancer complex (MSC-CD90-mwCNT-DOX) and the nano-cancer drug loading test group in the stem cells, and co-cultured on the coverslip for 48 hours. 0.05% Pluronic F-127 containing 4 μM of Fura-2 was reacted together in physiological saline for 15 min at dark room temperature and the stem cell-nano anticancer complex at excitation / emission 340/510 nm fluorescence wavelength using a fluorescence microscope. MSC-CD90-mwCNT-DOX) and changes in calcium signaling in lung cancer cells after treatment with the stem cell nano-cancer drug loading test group were analyzed and analyzed using MetaFluor system.

As a result, the intracellular calcium signaling change of lung cancer cells was the highest after treatment with stem cell-nano anticancer complex (MSC-CD90-mwCNT-DOX) compared to the nano-cancer drug loading test group in stem cells. It can be seen that the highest effect on the death (Figs. 19 to 21).

Experimental Example 8: Verification of the possibility of reverse differentiation of MSC

According to one embodiment of the present invention, the MSC remaining after cancer cell death of the stem cell-nano anticancer complex was examined for the possibility of tumor differentiation (tumorigenesis) into cancer. Specifically, 4 × 10 ⁵ cells were treated with free MSC (BM-MSC) and nano-cancer drug loading experiments in stem cells and stem cell-nano anticancer complexes (MSC-CD90-mwCNT-DOX) for a long time (240 hours). 10 ⁵ After co-culture with lung cancer cells (H1975) and staining of cancer cell specific markers (CD31, 34), the expression level was analyzed using FACS to investigate the possibility of reverse differentiation of MSC.

As a result, it was confirmed that the stem cell-nano anticancer complex (MSC-CD90-mwCNT-DOX) remaining after long-term treatment and cancer cell death did not reversely differentiate into cancer (FIG. 18).

Experimental Example 9: Preparation and Confirmation of Tumor Animal Model

In accordance with an embodiment of the present invention A549 non-pulmonary cancer cell line stably fluorescent / luminescent in order to confirm the killing effect of the cancer cells of the stem cell-nano anticancer complex in the animal model in vivo by luciferase activity (luciferase activity) A549-Luc-RFP) was constructed to establish a tumor mouse model.

Specifically, 2 × 10 ⁴ IU lentivirus was introduced per 2 × 10 ³ A549 lung cancer cells for the production of fluorescent / luminescent cells, followed by transduction for 24 hours, and confocal fluorescence 2-3 days after culture. Fluorescence was checked through a microscope, and then grown in a medium containing puromycin antibiotic for about 2-3 weeks to finally select a stable cell line. Since the fluorescent / luminescent cell line stably expresses luciferase, when the substrate, luciferin, is injected intravenously into mice, bioluminescence according to luciferase activity can be rapidly measured through cancer cell size change through IVIS imaging equipment. . Subsequently, female (n = 20) BALB / c nude mice (20 g, Gachon University Igil Female Diabetes Research Institute Laboratory Animal Lab) were temperature-controlled, and were bred under the light cycle (6: 00-18: 00) and free diet conditions. It was. On the other hand, in order to prepare a tumor animal model, non-small cell lung cancer (A549) cancer cells and luciferase-RFP fluorescence expressing non-small cell lung cancer (A549-luciferase-RFP) IV (intravenous) BALB / c mice ( 2 x 10 ⁶ cells) were used to generate lung tumors. After 1, 2 and 3 weeks, lung fluorescence was confirmed using an animal fluorescence imaging device (IVIS Spectrum In Vivo Imaging System, Perkinelmer). Lung tissue was collected and paraffin tissue slides were prepared, and then confirmed whether lung cancer was generated through immunochemical staining (immunohistochemistry) (FIG. 22).

As a result, it was confirmed that lung tumors were generated two weeks after the administration of the lung cancer cell line to the tumor animal model (FIG. 23).

Experimental Example 10 Analysis of Lung Tumor Suppression Effect of Stem Cell-Nano-cancer Complex

According to an embodiment of the present invention, the antitumor efficacy of the stem cell-nano anticancer complex was analyzed in an in vivo animal model.

Specifically, in vivo fluorescence imaging was confirmed using an IVIS animal fluorescence imaging system in an A549-luciferase-RFP tumor mouse model that fluoresces / luminesces the cancer cell death of the stem cell-nano anticancer complex. First, 2 weeks after injection of lung cancer cells (H1975, A549) emitting luciferase-RFP fluorescence into nude mice, doxorubicin anticancer agent (5 mg / kg), free MSC (2Ｘ10 ⁶ cells) and stem cell-nano anticancer complex (2Ｘ10 ⁶ cells) , 0.06 mg / kg) was injected intravenously twice at 5 day intervals, and luciferase was activated by injection of 150 mg / kg IV of luciferin 1 hour before measurement, and then fluorescence of lung cancer cells (H1975) was fluoresced every hour using fluorescence imaging equipment. The change was analyzed.

In addition, tissue immunochemistry showed that doxorubicin anticancer agent (low concentration: 0.02 mg / kg, high concentration: 5 mg / kg), carbon nanoanticancer (low concentration: 0.02 mg / kg), free MSC (4 weeks after tumor cell injection into lung tumor nude mice). 1 × 10 ⁶ cells) and a stem cell-nano anticancer complex (low concentration: 1 × ^{10 6} cells, 0.02 mg / kg; high concentration: 3 × 10 ⁶ cells, 0.06 mg / kg) four times intravenously every 5 days, and then the mice were sacrificed to sacrifice The tissues were recollected and paraffin tissue slides were prepared, followed by immunochemical analysis to confirm the effect of the stem cell-nano anticancer complex.

As a result, it was shown that administration of the stem cell-nano anticancer complex (hMSC-CD90-mwCNT-DOX) effectively inhibited the production of lung tumors that emit luciferase-RFP fluorescence (FIG. 24, FIG. 25). As a result, it was shown that administration of the stem cell-nano anticancer complex (hMSC-CD90-mwCNT-DOX) effectively inhibited the generation of lung tumors (FIG. 26).

In conclusion, the stem cell-nano anticancer complex according to one embodiment of the present invention (hMSC-CD90-mwCNT-DOX) is loaded with a nano-cancer drug exhibiting an anticancer effect at a lower concentration on the surface of the MSC excellent in the ability to migrate to cancer cells It can be used as an anticancer agent to maximize the efficacy of anticancer drugs and minimize side effects such as toxicity, and can be applied as a stem cell-nano anticancer agent that maximizes the anticancer drug efficacy to various cancers by selecting specific stem cells for each cancer type (FIG. 27). .

Although the present invention has been described with reference to the above-described embodiments, these are merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments and experimental examples are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

Claims (14)

Antibodies specific for mesenchymal stem cell specific surface antigens selected from the group consisting of CD90, CD73 and CD105 to carbon nanotube (CNT) or gold (Au) nanoparticles loaded with anticancer agents; Functional fragments of said antibody selected from the group consisting of Fab, F (ab ') ₂ , Fab', scFv, Fv, variable domain of camelid heavy chain (VHH), sdAb, diabody and triabody; Or antibody mimetics that specifically bind to said mesenchymal stem cell surface antigens selected from the group consisting of Affibody, Affilin, Affitin, Anticalin, Avimer, DARPin, Fynomer, monobody, variable lymphocyte receptor (VLR) and repebody ) Is attached, and the nanoparticles are bound to the mesenchymal stem cell surface, stem cell-nano anticancer complex. The method of claim 1,
The carbon nanotubes are multi-walled carbon nanotubes, stem cell-nano anticancer complex. The method of claim 2,
The multi-walled carbon nanotubes have a diameter of 5 to 50 nm, stem cell-nano anticancer complex. delete delete delete delete The method of claim 1,
The complex is a stem cell-nano anticancer complex, wherein the weight ratio of carbon nanotubes and the anticancer agent is 1: 1 to 1: 3. The method of claim 1,
The anticancer agent is doxorubicin, paclitaxel, ABT737, 5-fluorouracil, BCNU (carmustine), CCNU (lomustine), 6-mercaptopurine, nitrogen mustard, cyclophosphamide, vincristine, vinblastine, cisplatin, meso Stem cell-nano anticancer complex, which is trexate, cytarabine thiotepa, busulfan or procarbazine. delete The method of claim 1,
The gold nanoparticles are carboxylated PEG (polyethylene glycol), hyaluronic acid (hyaluronic acid), PHA (polyhydroxyalkanoates), PLGA {poly (lactic-co-glycolic acid)}, PLA {poly (lactic acid)} and PGA { poly (glycolic acid)} coated with a polymer material having a carboxyl group selected from the group consisting of, stem cell-nano anticancer complex. delete Claim 1 to 3, 8, 9, and claim 11, wherein the stem cell-nano anticancer complex of any one of the anticancer pharmaceutical composition containing as an active ingredient. A method of administering a therapeutically effective amount of a stem cell-nano anticancer complex of any one of claims 1 to 3, 8, 9, and 11 to a mammalian subject, excluding a human with cancer. Cancer treatment method of the individual comprising a.

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