JP2007204382A - Method for producing liposome - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for producing a liposome with adjusted particle size. <P>SOLUTION: The method comprises a step of introducing water droplets whose particle size is adjusted by microcapillary into an inner-membrane phospholipids-containing oily liquid to form a W/O emulsion, a step of catching the W/O emulsion, and a step of making the thus caught emulsion migrate into an aqueous phase that forms an oil/water interface via the oily liquid and outer-membrane lipids to add the outer-membrane lipids to the outer side of the W/O emulsion. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a method for producing liposomes.

Liposomes are formed by lipid bilayers such as phospholipids and have a capsule structure in which an aqueous phase is confined. Since the structure of liposomes is similar to biological membranes, various research materials and applications (cosmetics and drug delivery systems (DDS)) containing active ingredients are being studied (for example, Patent Documents 1 and 2). reference).
Here, liposomes are usually produced by suspending phospholipids in an aqueous solution to form multilamellar liposomes (so-called liposome stock solutions), followed by sonication.

On the other hand, a liposome production method has been proposed in which the inner membrane of a liposome is made of a W / O emulsion and lipid is added to the outer membrane of this emulsion (see, for example, Non-Patent Document 1). This method is performed as follows.
First, a small amount of water and lipid (which becomes the inner membrane of a liposome) are mixed in oil to prepare a W / O emulsion. Next, an oily liquid in which an outer membrane lipid (which becomes an outer membrane of a liposome) is dissolved is added to the aqueous phase to form a molecular membrane in which outer membrane lipids are arranged at the separation interface of oil and water. Then, the W / O emulsion is added to the oil phase side at the separation interface, centrifuged or stirred, and the W / O emulsion is transferred to the water phase side at the separation interface, and the outer membrane lipid is placed outside the W / O emulsion. Is added to produce liposomes.

  By the way, when studying the function of a biological substance in a cell, it is desired to construct a microlab (μm size reaction field) having almost the same spatial scale and structure as a cell. As such a microlab, a liposome whose structure is similar to that of a biological membrane can be used. For example, there is a microlab made of acrylic resin or glass. In addition, there is a technique in which a μm sized W / O emulsion is prepared with a surfactant such as sodium dodecyl sulfate (SDS), and a reaction substrate is enclosed in the emulsion to form a reaction field.

Japanese Patent Laid-Open No. 2003-2824 JP 2005-162712 A Langmuir 19 (2003) 2870-2879

  However, in the case of the conventional method for producing liposomes, it is difficult to control the size of the liposomes, and there is a problem that the obtained liposomes have non-uniform particle sizes or cannot obtain liposomes having a desired particle size. there were. In the case of the conventional technique, since a large number of liposomes are produced at a time by suspension, it is impossible to observe the state in which the W / O emulsion moves to the aqueous phase. It is difficult to apply the method to a microlab in which experiments are performed with corresponding to each other.

  Furthermore, in the case of the technique described in Non-Patent Document 1, it is difficult to produce liposomes having a particle size of 5 μm or more. This is presumably because the liposome has a very unstable structure, and when it becomes larger than 5 μm, the liposome is broken at the oil-water interface by centrifugation or the like.

  Conventionally, it has been difficult to fuse a plurality of liposomes or to introduce a reagent into liposome-encapsulated water droplets. If fusion of liposomes becomes possible, the inclusion water droplets can be mixed together, or a reagent can be introduced into the inclusion water droplets to control the start of the reaction in the liposome, so that it can be used as a microlab.

  Accordingly, an object of the present invention is to provide a method for producing liposomes having a controlled particle size. Another object of the present invention is to provide a method for producing a liposome capable of fusing a plurality of liposomes, introducing another substance into the liposome water droplets, or recovering a part of the water droplets. It is in.

  That is, the method for producing liposomes of the present invention comprises a step of introducing water droplets having a particle size adjusted by fine capillaries into an oily liquid containing inner membrane phospholipids to form a W / O emulsion; A step of capturing, a step of transferring the captured emulsion to an aqueous phase that forms an oil-water interface via the oily liquid and an outer membrane lipid, and adding the outer membrane lipid to the outside of the W / O emulsion; Have

  The method for producing liposomes of the present invention includes a step of capturing liposomes in an aqueous phase, and transferring the captured emulsion to an oily liquid that forms an oil-water interface via the aqueous phase and an outer membrane lipid. Forming a W / O emulsion from which the outer membrane lipid has been removed from the oily liquid, a plurality of the captured W / O emulsions, or encapsulating water droplets of the captured W / O emulsion And a step of collecting a part of the encapsulated water droplets, and the fused W / O emulsion, or W in which the other substance is introduced or a part of the encapsulated water droplets is collected. Transferring the / O emulsion to the aqueous phase via the oil / water interface and adding the outer membrane lipid to the outside of the W / O emulsion.

  It is preferable that the inner membrane phospholipid and the outer membrane phospholipid of the liposome are the same.

  According to the present invention, it is possible to produce liposomes having a controlled particle size. Moreover, according to the present invention, a liposome capable of fusing a plurality of liposomes, introducing another substance into the liposome-encapsulated water droplets, or recovering a part of the encapsulated water droplets can be produced.

Hereinafter, embodiments of the present invention will be described with reference to FIGS.
FIG. 1 shows a configuration example of an apparatus used in an embodiment of a manufacturing method of the present invention. In this figure, a microinjector, a micromanipulator, and an optical tweezer device (not shown) are provided.

A microinjector is a device to which a fine capillary is attached, and the internal pressure of the fine capillary can be adjusted by nitrogen gas or the like, and a solution can be sucked into or discharged from the tube. For example, a microinjector IM-300 manufactured by Narishige is commercially available.
The micromanipulator is a device that can move (manipulate) the above-described microcapillary three-dimensionally with high accuracy, and the microcapillary attached to the micromanipulator is connected to the microinjector. Many micromanipulators are commercially available.
Optical tweezers capture fine objects in water using light radiation pressure generated by condensing and irradiating laser light. In this optical tweezers, when laser light is irradiated to a fine object through a medium such as water, the laser light is refracted due to the difference in refractive index between the medium and the fine object, and the fine object is focused by the reaction to the accompanying change in the optical momentum. It is something to trap. Then, the fine object can be moved and transported by relatively moving the sample stage side including the fine object while the fine object is captured. Techniques for manipulating and collecting fine objects using such optical tweezers include, for example, techniques described in Japanese Patent Application Laid-Open Nos. 2001-71300 and 2001-21875.
In the present invention, these devices can be used as appropriate.

In FIG. 1, the above-described microinjector and micromanipulator are attached to a fine capillary (microcapillary) 50. The fine capillary 50 is placed in a hydrophobic cover glass 200 on a sample stage (not shown). An objective lens (microscope lens) 100 for operating while observing the movement of the fine capillary tube 50 is installed below the sample stage.
A rectangular frame 210 having an opening at the center is placed on the hydrophobic cover glass 200, and the oily liquid 10 is placed in a space formed by the opening of the frame 210 and the upper surface of the hydrophobic cover glass 200. And the aqueous phase 30 can be accommodated. Here, the opening of the frame body 210 has a rectangular shape, but a tapered protrusion extends from the middle point of each long side (left and right direction in FIG. 1) toward the opening center, and each protrusion is slightly near the opening center. It is separated. 1 is accommodated in the left space of FIG. 1 divided by the protrusions, the aqueous phase 30 is accommodated in the right space of FIG. 1, and an oil / water interface is formed in the space between the protrusions. The frame 210 can be formed of, for example, silicone rubber, and the thickness thereof can be set to 2 mm, for example.
The W / O emulsion and liposomes dispersed in the oily liquid 10 and the aqueous phase 30 can be captured by the fine capillaries 50.

  FIG. 2 is an enlarged view of the frame 210. In FIG. 2, each protrusion 212 extends from the midpoint of the long side of the opening of the frame body 210 toward the center of the opening, and among the openings divided by each protrusion 212, the left space is substantially D-shaped, and the right space is The left space is shaped symmetrically around the short side (vertical side in FIG. 2). In this embodiment, the long side and the short side of the frame 210 are 1.5 cm, the long side and the short side of the opening are 1.0 cm, and the interval between the protrusions 212 is 1.2 mm. Since the interval between the protrusions 212 is small, a lipid membrane layer serving as an oil-water interface can be reliably formed during this interval.

<Method for producing liposome according to the first invention of the present invention>
Next, the manufacturing method of the liposome which concerns on embodiment of 1st invention of this invention is demonstrated. The manufacturing method according to this embodiment includes a step of forming a W / O emulsion, a step of capturing the emulsion, and a step of adding the outer membrane lipid to the outside of the W / O emulsion.

(Formation of W / O emulsion)
In FIG. 1, a fine capillary 50 is inserted into an oily liquid 10, pressure is applied to the inside of the capillary 50 by a microinjector, and water in the capillary 50 is extruded to generate water droplets.
The oily liquid 10 contains an inner membrane phospholipid, and the inner membrane phospholipid has a hydrophobic group and a hydrophilic group. Therefore, the inner membrane phospholipid is spontaneously arranged around the water droplet in the oily liquid. A W / O emulsion 2 is obtained as shown.
The inner membrane phospholipid is not particularly limited. For example, phosphatidylcholine (hereinafter referred to as “PC”) or a derivative thereof, phosphatidylserine (hereinafter referred to as “PS”) or a derivative thereof, phosphatidylethanolamine (hereinafter referred to as “ PE ”) or a derivative thereof, SM (such as sphingomyelin) and a derivative thereof can be used. An example of the derivative is dioleyl (DO).

The oily liquid is not particularly limited as long as it stably disperses the inner membrane phospholipid. For example, mineral oil (mineral oil) can be used. The aqueous liquid is not particularly limited, and an active ingredient or the like encapsulated in the finally obtained liposome may be contained in the aqueous liquid.
(Liposome is a bilayer membrane. In addition, with this method (a method using a microinjector), the particle size can be controlled regardless of the encapsulated aqueous liquid. (Molecular membrane liposomes may be deformed or broken.)
Moreover, the density | concentration of the inner membrane phospholipid in an oily liquid can be about 1 mmol / L-10 micromol / L, for example. Here, as will be described later, when the inner membrane phospholipid and the outer membrane phospholipid are the same, the total concentration of the inner membrane phospholipid and the outer membrane phospholipid in the oily liquid may be within the above range.

In the present invention, the particle size of the liposome finally obtained can be adjusted by adjusting the particle size of the water droplets with fine capillaries. The particle diameter of the water droplet can be adjusted by appropriately changing the inner diameter of the capillary, the pressing force, the pressing time, and the like.
The particle diameter of the water droplet can be measured, for example, with an optical microscope. The particle diameter of the water droplet obtained by the microcapillary described above is, for example, about several μm to several hundred μm.

(Capturing W / O emulsion)
The W / O emulsion is captured by adsorbing the W / O emulsion to a fine capillary. Once the W / O emulsion is formed by adjusting the particle size of the water droplets by the above-described method, the particle size of the liposome is also determined thereby, so that the particle size of the W / O emulsion changes during the capture process by the fine capillaries. Absent.

(Addition of outer membrane lipid)
Next, by operating the micromanipulator to move the captured W / O emulsion 2 from the oily liquid 10 to the aqueous phase 30, the outer membrane lipid 4 is added to the outside of the W / O emulsion 2 and the liposome 6 is formed. To manufacture.
Here, as shown in FIG. 3, the outer membrane lipid 4 is arranged in a single layer at the oil-water interface between the oily liquid 10 and the aqueous phase 30, and the W / O emulsion 2 passes through this outer membrane lipid 4 layer. Thus, the outer membrane lipid 4 is added to the outside of the W / O emulsion 2 when shifting to the aqueous phase.
As a method for aligning the outer membrane lipid 4 at the oil-water interface, for example, the lipid may be dissolved in the oily liquid and the oily liquid may be brought into contact with water, whereby a part of the lipid in the oily liquid is obtained. Voluntarily line up in a single layer at the oil-water interface. In this case, the same inner membrane lipid and outer membrane lipid constituting the W / O emulsion are used.

As described above, according to the method for producing a liposome according to the embodiment of the first invention of the present invention, the particle size of the liposome (particle size of the encapsulated water droplets) can be adjusted to a desired value. There is an advantage that only a very small amount of sample, reaction reagent, etc. are required when the inside is used in a microlab reaction system. In addition, since the process from the creation of individual water droplets to the formation of liposomes can be associated, it is suitable as a microlab.
For example, the present invention can be applied to examination of medicine, biological research, biochemical reaction and the like.

<Method for producing liposome according to the second invention of the present invention>
Next, the manufacturing method of the liposome which concerns on embodiment of 2nd invention of this invention is demonstrated. The production method according to this embodiment includes a step of capturing liposomes in an aqueous phase, a step of transferring the captured liposomes to an oily liquid, and the obtained W / O emulsion, or of the W / O emulsion. It has a step of introducing another substance into the encapsulated water droplets or recovering a part of the encapsulated water droplets, and a step of transferring these W / O emulsions to the aqueous phase.
As the apparatus used in the embodiment of the second invention, the apparatus shown in FIGS. 1 and 2 can be used as in the case of the first invention.

(Capturing liposomes in the aqueous phase)
The second invention is premised on the use of a predetermined liposome in advance, and is characterized in that various operations are performed in the state of a W / O emulsion from which the outer lipid of the liposome has been removed, and then returned to the liposome again.
As shown in FIG. 4, first, predetermined liposomes 6 are dispersed in the aqueous phase 30, and the liposomes 6 are adsorbed and captured by fine capillaries.

(Transfer of liposome to oily liquid)
Next, when the micromanipulator is operated to transfer the captured liposome 6 from the aqueous phase 30 to the oily liquid 10, the outer membrane lipid 4 of the liposome 6 is removed at the oil-water interface, and the W / O emulsion 2 is obtained.

(Operation of W / O emulsion)
Next, various operations are performed on the W / O emulsion 2 obtained with the oily liquid 10. The operation of the W / O emulsion 2 includes the fusion of a plurality of W / O emulsions, the introduction of other substances into the water droplets contained in the W / O emulsion, and the collection of some of the water droplets contained (collection, analysis, etc.). Can be mentioned.
Usually, liposomes have outer membrane lipids, so it is difficult to fuse multiple liposomes or introduce other substances into the liposome's encapsulated water droplets. By making it exist, these operations become easy. In addition, the fusion in the oil phase can be induced by bringing water droplets into contact with each other by optical tweezers, an electric field, or the like, in addition to the microcapillary attached with the microinjector and the micromanipulator as described above.

Examples of other substances introduced into the W / O emulsion include a reactive agent that reacts with a reaction substrate contained in the W / O emulsion. For example, when the reaction substrate is a protein, an enzyme that specifically reacts with the protein becomes a reactive agent. Examples of a method for introducing another substance include a method in which a micropipette is inserted into a W / O emulsion by a micromanipulator and a substance in the pipette is introduced.
As the reaction substrate, biological materials for synthesizing various proteins, DNA, and the like, which are biological materials, can be suitably used. The biological material is very sensitive to the surrounding environment, and it is difficult to control the reaction of the biological material in a conventional micrometer-sized microspace. According to the embodiment of the present invention, a biological material can be surrounded by a phospholipid similar to the main component of a cell membrane, and a minute reaction space whose inside is similar to the intracellular environment is created so that the biological material is not deactivated. The reaction can be controlled.

Also, instead of introducing the reactant into the W / O emulsion in which the reaction substrate is encapsulated, a first W / O emulsion in which the reaction substrate is encapsulated, and a second W / O emulsion in which the reactant is encapsulated, Can be allowed to proceed with the fusion as a starting time.
The reaction can also be initiated by irradiating the W / O emulsion in which the reaction substrate is encapsulated with wavelength light or electromagnetic waves that react with the reaction substrate.
In either case, the reaction can be allowed to proceed in a liposome-like environment by adding an outer membrane lipid as described below after the start of the reaction.

(Addition of outer membrane lipid)
Next, as in the case of the first invention shown in FIG. 3, the outer membrane lipid 4 is added to the outside of the W / O emulsion 2 by capturing the W / O emulsion and transferring it to the aqueous phase. Liposomes 6 can be obtained.
Thus, in the case of the second invention, since the fusion of the liposome-encapsulated water droplets and substance introduction can be easily performed, for example, the reaction of the liposome-encapsulated water droplets can be accurately controlled, and the reaction start can be controlled in real time. Suitable as a microlab.

It is a perspective view which shows the structural example of the apparatus used for embodiment of the manufacturing method of this invention. 3 is an enlarged top view of a frame body 210. FIG. It is a figure showing an embodiment of the 1st invention of the present invention. It is a figure which shows embodiment of the 2nd invention of this invention.

Explanation of symbols

4 Outer membrane lipid 10 Oily liquid 30 Aqueous phase 50 Fine capillary tube 100 Objective lens

Claims (3)

Introducing water droplets having a particle size adjusted by fine capillaries into an oily liquid containing inner membrane phospholipids to form a W / O emulsion;
Capturing the W / O emulsion;
Producing liposomes having a step of transferring the captured emulsion to an aqueous phase forming an oil-water interface via the oily liquid and an outer membrane lipid, and adding the outer membrane lipid to the outside of the W / O emulsion Method. Capturing the liposomes in the aqueous phase;
The trapped emulsion is transferred to an oily liquid that forms an oil-water interface via the aqueous phase and outer membrane lipid, and a W / O emulsion in which the outer membrane lipid is removed from the liposome is formed in the oily liquid. And a process of
Fusing a plurality of the captured W / O emulsions, or introducing another substance into the encapsulated water droplets of the captured W / O emulsion, or recovering a part of the encapsulated water droplets;
The fused W / O emulsion, or the W / O emulsion in which the other substance has been introduced or a part of the water droplets contained therein is recovered, is transferred to the water phase via the oil / water interface, and the W / O And a step of adding the outer membrane lipid to the outside of the O emulsion.   The method for producing a liposome according to claim 1 or 2, wherein the inner membrane phospholipid and the outer membrane phospholipid of the liposome are the same.