JP2017079660A - Method for producing cell concentrated solution using cell separation filter - Google Patents
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Abstract
Description
本発明は、細胞分離フィルターを用いて、細胞含有液から効率的に細胞濃縮液を製造する方法に関する。 The present invention relates to a method for efficiently producing a cell concentrate from a cell-containing solution using a cell separation filter.
血液学や科学テクノロジーの急速な進歩に伴い、全血・骨髄・臍帯血・組織抽出物をはじめとする体液から必要な血液分画のみを分離して患者に投与することで治療効果を高め、さらに、治療に必要のない分画は投与しないことで副作用を抑制するという治療スタイルが広く普及している。 With rapid advances in hematology and scientific technology, only the necessary blood fraction is separated from body fluids such as whole blood, bone marrow, umbilical cord blood and tissue extract and administered to patients, increasing the therapeutic effect, Furthermore, a treatment style that suppresses side effects by not administering fractions that are not necessary for treatment has become widespread.
例えば、血液輸血がその1つである。赤血球製剤は、出血及び赤血球が不足する場合又は赤血球の機能低下により酸素が欠乏している場合に使用される血液製剤である。赤血球製剤には、異常な免疫反応や移植片対宿主病(GVHD)などの副作用を誘導する白血球は不要なため、フィルターで白血球を除去する必要があり、場合によっては白血球に加えて血小板も除去することもある。 For example, blood transfusion is one of them. An erythrocyte product is a blood product that is used when bleeding and erythrocytes are deficient or when oxygen is deficient due to reduced function of erythrocytes. Erythrocyte products do not require leukocytes that induce side effects such as abnormal immune responses or graft-versus-host disease (GVHD), so it is necessary to remove leukocytes with a filter, and in some cases, in addition to leukocytes, also remove platelets Sometimes.
加えて、近年、白血病や癌治療に向けた造血幹細胞移植が盛んに行われるようになり、治療に必要な造血幹細胞を含む白血球群を分離し投与する方法がとられている。この造血幹細胞のソースとしては骨髄、末梢血又は臍帯血が知られており、ドナーの負担が少ないこと、増殖能力が優れていること等の利点から注目を浴びている。 In addition, in recent years, hematopoietic stem cell transplantation for leukemia and cancer treatment has been actively performed, and a method of separating and administering leukocyte groups containing hematopoietic stem cells necessary for treatment has been taken. Bone marrow, peripheral blood or umbilical cord blood is known as a source of this hematopoietic stem cell, and is attracting attention because of its advantages such as low burden on the donor and excellent proliferation ability.
その他、骨、軟骨、筋肉、脂肪など様々な組織に分化できる間葉系幹細胞を用いた治療方法も注目されているものの、間葉系幹細胞は成人の骨髄や臍帯血中に104から106個に1つの割合であり非常に存在頻度が少ないため、効率的に製造することが望まれている。 In addition, although treatment methods using mesenchymal stem cells that can differentiate into various tissues such as bone, cartilage, muscle, and fat are also attracting attention, mesenchymal stem cells are 10 4 to 10 6 in adult bone marrow and umbilical cord blood. Since the ratio is one per piece and the existence frequency is very low, efficient production is desired.
そこで、細胞を効率的に分離・濃縮でき、且つ操作性が簡便である細胞濃縮液の製造方法として、不織布を積層したフィルターを用いた細胞濃縮液の製造方法が開示されている(特許文献1)。また、不織布の目詰まりを抑制するために、特定の穴面積率で加工した不織布を異なる不織布の間に積層したフィルターを用いて白血球を除去する方法や(特許文献2)、顆粒球のみが選択的に捕捉される細胞分離フィルターを用いて、単核球を効率良く回収する方法が開示されている。(特許文献3)。しかし、当該方法においては、回収率の向上や不要な細胞の混入率を抑制するために、目的細胞に適した不織布を適時設計しなければならず、細胞種ごとに不織布を開発しなければならない。 Therefore, as a method for producing a cell concentrate that can efficiently separate and concentrate cells and is easy to operate, a method for producing a cell concentrate using a filter laminated with nonwoven fabric is disclosed (Patent Document 1). ). In addition, in order to suppress clogging of the nonwoven fabric, a method of removing white blood cells using a filter in which nonwoven fabrics processed with a specific hole area ratio are laminated between different nonwoven fabrics (Patent Document 2), or only granulocytes are selected. A method for efficiently recovering mononuclear cells using a cell separation filter that is trapped automatically is disclosed. (Patent Document 3). However, in this method, in order to improve the recovery rate and to suppress the contamination rate of unnecessary cells, a nonwoven fabric suitable for the target cell must be designed in a timely manner, and a nonwoven fabric must be developed for each cell type. .
上記のように、効率的に細胞濃縮液を製造するためには、操作性が簡便である細胞分離フィルターを用いた分離・濃縮方法が好ましいが、細胞分離フィルターの性能を上げようとすれば、特定細胞に適した細胞分離フィルターとなり汎用性が乏しく、細胞種ごとに不織布を開発しなければならないという問題点が挙げられ、その解決方法は未だ見出されていないのが現状である。 As described above, in order to efficiently produce a cell concentrate, a separation / concentration method using a cell separation filter that is easy to operate is preferable, but if it is intended to improve the performance of the cell separation filter, The cell separation filter is suitable for specific cells and is not very versatile, and there is a problem that a nonwoven fabric must be developed for each cell type. A solution to this problem has not yet been found.
本発明の目的は、細胞分離フィルターを用いて細胞含有液から細胞濃縮液を製造する方法における上記問題点を解決することを目的とする。具体的には、回収する目的の細胞種に適した細胞分離フィルターを設計せずとも、効率的に細胞含有液から細胞濃縮液を製造する方法を提供する。 An object of the present invention is to solve the above-mentioned problems in a method for producing a cell concentrate from a cell-containing solution using a cell separation filter. Specifically, the present invention provides a method for efficiently producing a cell concentrate from a cell-containing solution without designing a cell separation filter suitable for the cell type to be collected.
本発明者らは、製造方法の処理工程に着目し、前記課題を解決すべく鋭意検討を重ねた結果、細胞含有液を分割して細胞分離フィルターに通液し細胞分離材に細胞を捕捉させた後、回収液を分割して細胞分離フィルターに通液し細胞を回収することで、細胞分離フィルターを最適化せずとも有核細胞の回収率を向上させることができ、且つ細胞分離材を細胞種に応じて変更しなくても良いことから、汎用性に富むことを見出し、本発明を完成するに至った。 The present inventors paid attention to the processing steps of the production method, and as a result of intensive studies to solve the above problems, the cell-containing liquid was divided and passed through a cell separation filter, and the cells were captured by the cell separation material. After that, the recovered solution is divided and passed through the cell separation filter to recover the cells, so that the recovery rate of nucleated cells can be improved without optimizing the cell separation filter, and the cell separation material can be used. Since it does not have to be changed according to the cell type, it has been found that it is highly versatile, and the present invention has been completed.
即ち、本発明の要旨は以下の通りである。
〔1〕導入口及び導出口を備えた細胞分離フィルターを用いて細胞含有液から細胞濃縮液を製造する方法であって、
前記導入口から前記細胞含有液を分割して導入し、前記細胞分離フィルターに細胞を捕捉させた後、前記導出口から回収液を分割して導入し、前記細胞濃縮液を前記細胞分離フィルターから回収する工程を有し、且つ、最初に前記細胞分離フィルターに通液する細胞含有液の処理量(mL)と細胞含有液の全量(mL)の比(最初に前記細胞分離フィルターに通液する細胞含有液の処理量(mL)/細胞含有液の全量(mL))が、0.5以上、1未満であることを特徴とする方法。
〔2〕最初に前記細胞分離フィルターに通液する回収液の処理量(mL)と回収液の全量(mL)の比(最初に前記細胞分離フィルターに通液する回収液の処理量(mL)/回収液の全量(mL))が、0より大きく、0.61以下であることを特徴とする〔1〕に記載の方法。
〔3〕前記導入口から細胞含有液を分割して導入する回数が2又は3回であることを特徴とする〔1〕又は〔2〕に記載の方法。
〔4〕前記導出口から回収液を分割して導入する回数が2又は3回であることを特徴とする〔1〕〜〔3〕のいずれかに記載の方法。
〔5〕前記回収液が生理食塩水、細胞培養用培地、ヒドロキシエチルスターチ、及びデキストランの群より選択される1つ以上を含むことを特徴とする、〔1〕〜〔4〕のいずれかに記載の方法。
〔6〕細胞含有液が血液、骨髄液、臍帯血、月経血、細胞培養液、又はそれらの希釈液のいずれか1つである〔1〕〜〔5〕のいずれかに記載の方法。
〔7〕前記導入口から細胞含有液を分割して導入する前に、前記導入口からプライミング液を導入し、前記細胞分離フィルターをプライミングする工程を含む、〔1〕〜〔6〕のいずれかに記載の方法。
〔8〕前記導出口から回収液を分割して導入する前に、前記導入口から洗浄液を導入し、前記細胞分離フィルターを洗浄する工程を含む、〔1〕〜〔7〕のいずれかに記載の方法。
That is, the gist of the present invention is as follows.
[1] A method for producing a cell concentrate from a cell-containing solution using a cell separation filter having an inlet and an outlet,
The cell-containing liquid is divided and introduced from the inlet, and after the cells are captured by the cell separation filter, the recovered liquid is divided and introduced from the outlet, and the cell concentrate is removed from the cell separation filter. A ratio of the treatment amount (mL) of the cell-containing solution that first passes through the cell separation filter and the total amount (mL) of the cell-containing solution (mL) that passes through the cell separation filter A method wherein the treatment amount of the cell-containing solution (mL) / total amount of the cell-containing solution (mL)) is 0.5 or more and less than 1.
[2] Ratio of the amount of treated liquid (mL) first passed through the cell separation filter and the total amount of the collected liquid (mL) (the amount of treated recovery liquid (mL) first passed through the cell separation filter) / Total amount of recovered liquid (mL)) is greater than 0 and 0.61 or less. The method according to [1].
[3] The method according to [1] or [2], wherein the cell-containing solution is divided and introduced two or three times from the introduction port.
[4] The method according to any one of [1] to [3], wherein the number of times the recovered liquid is introduced separately from the outlet is 2 or 3.
[5] Any one of [1] to [4], wherein the recovered solution contains one or more selected from the group of physiological saline, cell culture medium, hydroxyethyl starch, and dextran. The method described.
[6] The method according to any one of [1] to [5], wherein the cell-containing solution is any one of blood, bone marrow fluid, umbilical cord blood, menstrual blood, cell culture fluid, or a diluted solution thereof.
[7] The method according to any one of [1] to [6], comprising a step of introducing a priming solution from the introduction port and priming the cell separation filter before dividing and introducing the cell-containing solution from the introduction port. The method described in 1.
[8] The method according to any one of [1] to [7], including a step of introducing a washing solution from the introduction port and washing the cell separation filter before dividing and introducing the recovered solution from the outlet port. the method of.
本発明の細胞分離方法を用いることにより、回収する細胞種及び細胞分離フィルターの材質に影響されずに、効率的に細胞含有液から細胞濃縮液を製造することが可能となる。また、効率的に細胞濃縮液を製造できるため、ドナー患者の負担低減が期待される。 By using the cell separation method of the present invention, it is possible to efficiently produce a cell concentrate from a cell-containing solution without being affected by the cell type to be collected and the material of the cell separation filter. Moreover, since the cell concentrate can be produced efficiently, the burden on the donor patient is expected to be reduced.
以下、本発明を詳細に説明する。
本発明は、導入口及び導出口を備えた細胞分離フィルターを用いて細胞含有液から細胞濃縮液を製造する方法であって、
前記導入口から前記細胞含有液を分割して導入し、前記細胞分離フィルターに細胞を捕捉させた後、前記導出口から回収液を分割して導入し、前記細胞濃縮液を前記細胞分離フィルターから回収する工程を有し、且つ、最初に前記細胞分離フィルターに通液する細胞含有液の処理量(mL)と細胞含有液の全量(mL)の比(最初に前記細胞分離フィルターに通液する細胞含有液の処理量(mL)/細胞含有液の全量(mL))が、0.5以上、1未満であることを特徴とする。
Hereinafter, the present invention will be described in detail.
The present invention is a method for producing a cell concentrate from a cell-containing solution using a cell separation filter having an inlet and an outlet,
The cell-containing liquid is divided and introduced from the inlet, and after the cells are captured by the cell separation filter, the recovered liquid is divided and introduced from the outlet, and the cell concentrate is removed from the cell separation filter. A ratio of the treatment amount (mL) of the cell-containing solution that first passes through the cell separation filter and the total amount (mL) of the cell-containing solution (mL) that passes through the cell separation filter The treatment amount of the cell-containing liquid (mL) / total amount of the cell-containing liquid (mL)) is 0.5 or more and less than 1.
本発明の細胞分離フィルターとは、上部又は下部のいずれかに導入口、その反対側に導出口を備える容器の内部に細胞分離材を充填したものを指し、前記導入口とは前記容器外部から前記容器内部に細胞含有液を導入する口であり、前記導出口とは、前記導入口の上下方向に対して反対側に設けられ、細胞分離操作の際に細胞分離材を通過した液体を容器外部へ排出するための口である。 The cell separation filter of the present invention refers to one in which a cell separation material is filled inside a container having an inlet at either the upper part or the lower part and an outlet at the opposite side, and the inlet is from the outside of the container A port for introducing a cell-containing liquid into the container, wherein the outlet port is provided on the opposite side of the inlet port in the vertical direction, and the liquid that has passed through the cell separation material during the cell separation operation is stored in the container. It is a mouth for discharging to the outside.
前記導入口及び導出口の個数については特に限定はないが、それぞれ1つ以上備え付けられれば良い。また、前記導入口又は導出口が設けられる配置は特に限定されないが、例えば、デットエンドフローやクロスフローを採用することができ、当業者の目的によって設計される。 There are no particular restrictions on the number of the inlets and outlets, but one or more each may be provided. Moreover, although the arrangement | positioning in which the said inlet or outlet is provided is not specifically limited, For example, a dead end flow and a cross flow can be employ | adopted and it designs by the objective of those skilled in the art.
前記容器の形状としては、前記細胞分離材を充填できる形状であればよく、細胞分離材が容器内部で固定できる構造であれば特に限定はないが、例えば、球、コンテナ、カセット、バッグ、チューブ等が挙げられる。 The shape of the container is not particularly limited as long as it is a shape that can be filled with the cell separation material, and the cell separation material can be fixed inside the container. For example, a sphere, a container, a cassette, a bag, a tube Etc.
前記細胞分離材とは、細胞含有液から目的の細胞を捕捉できるものをいい、形態としては特に限定されず、連通孔構造の多孔質体、繊維の集合体、織物等が挙げられる。好ましくは繊維で構成されるものであり、より好ましくは不織布である。 The cell separation material refers to a material that can capture target cells from a cell-containing solution, and the form is not particularly limited, and examples thereof include a porous body having a continuous pore structure, a fiber aggregate, and a woven fabric. Preferably it is comprised with a fiber, More preferably, it is a nonwoven fabric.
前記細胞分離材の材質としては、例えば、ポリプロピレン、ポリエチレン、高密度ポリエチレン、低密度ポリエチレン等のポリオレフィン、ポリエステル、塩化ビニル、ポリビニルアルコール、塩化ビニリデン、レーヨン、ビニロン、ポリスチレン、アクリル(ポリメチルメタクリレート、ポリヒドロキシエチルメタクリレート、ポリアクロニトリル、ポリアクリル酸、ポリアクリレート等)、ナイロン、ポリウレタン、ポリイミド、アラミド、ポリアミド、キュプラ、ケブラー、カーボン、フェノール、テトロン、パルプ、麻、セルロース、ケナフ、キチン、キトサン、ガラス、綿等を挙げることができる。中でも、ポリエステル、ポリプロピレン、アクリル、レーヨン、ナイロン、ポリブチレンテレフタラート、ポリエチレンテレフタラート等の高分子を好適に用いることができる。前記細胞分離材は、これらの材質のうち、単一の材質からなってもよいし、複数の材質を組み合わせた複合材からなってもよい。 Examples of the material for the cell separation material include polyolefins such as polypropylene, polyethylene, high density polyethylene and low density polyethylene, polyester, vinyl chloride, polyvinyl alcohol, vinylidene chloride, rayon, vinylon, polystyrene, acrylic (polymethyl methacrylate, poly Hydroxyethyl methacrylate, polyacrylonitrile, polyacrylic acid, polyacrylate, etc.), nylon, polyurethane, polyimide, aramid, polyamide, cupra, kevlar, carbon, phenol, tetron, pulp, hemp, cellulose, kenaf, chitin, chitosan, glass And cotton. Among these, polymers such as polyester, polypropylene, acrylic, rayon, nylon, polybutylene terephthalate, and polyethylene terephthalate can be suitably used. The cell separation material may be composed of a single material among these materials, or may be composed of a composite material obtained by combining a plurality of materials.
細胞分離材の平均繊維径としては、目的の細胞の種類に合わせて適宜選択すればよく、特に限定はないが、例えば、目的の細胞が造血幹細胞であれば、2〜6μm、間葉系幹細胞であれば、3〜35μmの平均繊維径を選択することが好ましい。 The average fiber diameter of the cell separation material may be appropriately selected according to the type of the target cell, and is not particularly limited. For example, if the target cell is a hematopoietic stem cell, 2 to 6 μm, a mesenchymal stem cell If so, it is preferable to select an average fiber diameter of 3 to 35 μm.
本発明の細胞含有液とは、幹細胞や白血球のように様々な治療で用いられる細胞を含有する液体であれば何でもよく、例えば血液、骨髄液、臍帯血、月経血、細胞培養液、又はそれらの希釈液や、細胞培養後の懸濁液などが挙げられる。 The cell-containing liquid of the present invention may be any liquid that contains cells used in various treatments such as stem cells and leukocytes, such as blood, bone marrow fluid, umbilical cord blood, menstrual blood, cell culture fluid, or those. Or a suspension after cell culture.
前記細胞としては有核細胞が好ましく、前記有核細胞としては、人工多能性幹細胞(iPS細胞)、胚性幹細胞(ES細胞)、間葉系幹細胞、脂肪由来間葉系細胞、脂肪由来間質幹細胞、多能性成体幹細胞、骨髄ストローマ細胞、造血幹細胞等の多分化能を有する生体幹細胞、T細胞、B細胞、キラーT細胞(細胞障害性T細胞)、NK細胞、NKT細胞、制御性T細胞などのリンパ球系の細胞、マクロファージ、単球、樹状細胞、顆粒球、神経細胞、筋細胞、線維芽細胞、肝細胞、心筋細胞などの体細胞又は前記有核細胞に遺伝子の導入や分化などの処理を行った細胞が挙げられる。 The cells are preferably nucleated cells, and the nucleated cells include induced pluripotent stem cells (iPS cells), embryonic stem cells (ES cells), mesenchymal stem cells, adipose-derived mesenchymal cells, adipose-derived cells Stem cells, pluripotent adult stem cells, bone marrow stromal cells, hematopoietic stem cells and other multipotent biological stem cells, T cells, B cells, killer T cells (cytotoxic T cells), NK cells, NKT cells, regulatory Introduction of genes into lymphocyte cells such as T cells, macrophages, monocytes, dendritic cells, granulocytes, neuronal cells, muscle cells, fibroblasts, hepatocytes, cardiomyocytes, or the nucleated cells And cells subjected to treatment such as differentiation.
本発明の細胞濃縮液とは、処理前の前記細胞含有液よりも、液中における目的の細胞の細胞濃度(cell/mL)が濃い液のことをいう。また、前記細胞含有液よりも目的の細胞以外の不要物(例えば、赤血球、血小板等)が除去された液である。 The cell concentrate of the present invention refers to a solution having a higher cell concentration (cell / mL) of target cells in the solution than the cell-containing solution before treatment. Moreover, it is a liquid from which unnecessary substances other than the target cells (for example, red blood cells, platelets, etc.) are removed from the cell-containing liquid.
本発明の分割とは、細胞分離フィルターに通液する所望の液体(例えば、細胞含有液、回収液等)の全量を、複数に細分化することを指す。分割の態様としては、液体の全量を細分化できる方法であれば特に限定されないが、例えば、所望の液体が全量入ったバッグを複数の異なるバッグに細分化してもよいし、所望の液体が全量入ったバッグから少量ずつ液体を細胞分離フィルター内に導入して、細分化してもよい。 The division of the present invention refers to dividing the total amount of a desired liquid (for example, a cell-containing liquid, a collected liquid, etc.) that passes through the cell separation filter into a plurality of parts. The mode of division is not particularly limited as long as it is a method that can subdivide the total amount of liquid. For example, a bag containing the entire amount of the desired liquid may be subdivided into a plurality of different bags, or the total amount of the desired liquid A small amount of liquid may be introduced into the cell separation filter from the contained bag and subdivided.
本発明において、前記細胞含有液を分割して導入する回数は、細胞含有液の液量に応じて設計すれば、特に限定されないが、処理時間の短縮及び操作性の簡素化の観点より、2又は3回で行うことが好ましく、2回で行うことがより好ましい。 In the present invention, the number of times of dividing and introducing the cell-containing liquid is not particularly limited as long as it is designed according to the amount of the cell-containing liquid, but from the viewpoint of shortening the processing time and simplifying operability, Or it is preferable to carry out 3 times, and it is more preferable to carry out 2 times.
本発明において、前記回収液を分割して導入する回数は、回収液の液量に応じて設計すれば、特に限定されないが、前記細胞含有液の分割する回数と同様に、処理時間の短縮及び操作性の簡素化の観点より、2又は3回が好ましく、2回がより好ましい。 In the present invention, the number of times the divided liquid is introduced in a divided manner is not particularly limited as long as it is designed according to the amount of the collected liquid, but as with the number of times the cell-containing liquid is divided, the processing time is reduced and From the viewpoint of simplification of operability, it is preferably 2 or 3 times, more preferably 2 times.
前記細胞分離フィルターの導入口から前記細胞含有液を導入する形態としては、前記細胞含有液をポンプやシリンジ等で加圧したり、または細胞含有液をプールしたバック等から自然落下すればよい。 As a mode of introducing the cell-containing liquid from the introduction port of the cell separation filter, the cell-containing liquid may be pressurized by a pump, a syringe, or the like, or may be naturally dropped from a bag in which the cell-containing liquid is pooled.
前記回収液の導入において、細胞を捕捉した細胞分離フィルターの導出口から回収液を導入することで、細胞分離フィルターから細胞を回収液中に分離させ、この回収液を導入口から回収用のバッグなどに導入することで目的の細胞を回収することができる。 In the introduction of the recovery liquid, the recovery liquid is introduced from the outlet of the cell separation filter that has captured the cells, whereby the cells are separated from the cell separation filter into the recovery liquid, and the recovery liquid is recovered from the inlet to the recovery bag. It is possible to recover the target cells by introducing them into the above.
前記回収液は、その後の用途に合わせて、適宜設計すればよいが、例えば、生理食塩水、細胞培養用培地、ヒドロキシエチルスターチ、及びデキストランより1つ以上を用いればよい。また、捕捉された細胞を回収する際、フィルターに対する細胞の接着性により回収液の効果が異なるため、例えば、フィルターと接着性の高い細胞を回収する場合には、粘度が高いヒドロキシエチルスターチやデキストランを好適に使用することができる。 The recovered solution may be appropriately designed in accordance with the subsequent use. For example, one or more of saline, cell culture medium, hydroxyethyl starch, and dextran may be used. In addition, when recovering captured cells, the effect of the recovery solution differs depending on the adhesion of the cells to the filter. For example, when recovering cells with high adhesiveness to the filter, hydroxyethyl starch or dextran with high viscosity is collected. Can be preferably used.
前記細胞分離フィルターの導出口から回収液を導入する形態としては、シリンジを用いてプランジャーを勢いよく押す方法やポンプを用いて送液する方法等が挙げられる。 Examples of the form in which the collection liquid is introduced from the outlet of the cell separation filter include a method of pushing the plunger with a syringe and a method of feeding with a pump.
本発明は、細胞含有液の処理量(mL)と細胞含有液の全量(mL)の比(最初に前記細胞分離フィルターに通液する細胞含有液の処理量(mL)/細胞含有液の全量(mL))が、0.5以上、1未満にすることで、目詰まり(接着性の高い細胞の残存など)を低減し、効率的に細胞を回収することができる。ここで、細胞含有液の処理量(mL)と細胞含有液の全量(mL)の比が0.5未満であるとフィルターに分割して導入する細胞含有液量に偏りが生じ、フィルター内に凝集性の高い細胞やタンパク質が残存しやすくなる。さらに、細胞含有液の処理量(mL)と細胞含有液の全量(mL)の比(最初に前記細胞分離フィルターに通液する細胞含有液の処理量(mL)/細胞含有液の全量(mL))を、0.5以上、0.94以下に設定することで、処理時間の大幅な改善や細胞濃縮液中の有核細胞含有濃度(cell/mL)の向上といった効果が得られる。 The present invention relates to the ratio of the treatment amount of the cell-containing solution (mL) to the total amount of the cell-containing solution (mL) (the treatment amount of the cell-containing solution that first passes through the cell separation filter (mL) / the total amount of the cell-containing solution). (ML)) is 0.5 or more and less than 1, clogging (remaining cells with high adhesiveness, etc.) can be reduced and cells can be efficiently recovered. Here, if the ratio of the treatment amount of the cell-containing liquid (mL) to the total amount of the cell-containing liquid (mL) is less than 0.5, the amount of the cell-containing liquid to be introduced dividedly into the filter is biased, Highly aggregated cells and proteins are likely to remain. Furthermore, the ratio of the treatment amount of the cell-containing solution (mL) to the total amount of the cell-containing solution (mL) (the treatment amount of the cell-containing solution initially passed through the cell separation filter (mL) / the total amount of the cell-containing solution (mL )) Is set to 0.5 or more and 0.94 or less, effects such as significant improvement in the processing time and improvement in the concentration of nucleated cells (cell / mL) in the cell concentrate can be obtained.
本発明において、前記細胞含有液の液量について特に制限はないが、処理時間の短縮やドナー患者の負担を軽減する観点より、上限として1000mL以下、900mL以下、800mL以下、700mL以下、600mL以下、500mL以下、400mL以下、300mL以下、200mL以下、150mL以下、下限として10mL以上、20mL以上、30mL以上、40mL以上、50mL以上、60mL以上、70mL以上、80mL以上、90mL以上、100mL以上の液量で行なってもよい。 In the present invention, the amount of the cell-containing solution is not particularly limited, but from the viewpoint of shortening the processing time and reducing the burden on the donor patient, the upper limit is 1000 mL or less, 900 mL or less, 800 mL or less, 700 mL or less, 600 mL or less, 500 mL or less, 400 mL or less, 300 mL or less, 200 mL or less, 150 mL or less, the lower limit is 10 mL or more, 20 mL or more, 30 mL or more, 40 mL or more, 50 mL or more, 60 mL or more, 70 mL or more, 80 mL or more, 90 mL or more, 100 mL or more You may do it.
本発明は最初に前記細胞分離フィルターに通液する回収液の処理量(mL)と回収液の全量(mL)の比(最初に前記細胞分離フィルターに通液する回収液の処理量(mL)/回収液の全量(mL))が、0より大きく、0.61以下であることを特徴とする。最初に前記細胞分離フィルターに通液する回収液の処理量(mL)と回収液の全量(mL)の比(最初に前記細胞分離フィルターに通液する回収液の処理量(mL)/回収液の全量(mL))が、0より大きく、0.61以下に設定することで、単に回収液を分割して導入するよりも、さらに効率的に細胞を回収することができる。回収液を分割して導入するにあたっては、最初に導入する回収液量を少なくすることで、効率的に細胞を回収することできる。より好ましくは、最初に前記細胞分離フィルターに通液する回収液の処理量(mL)と回収液の全量(mL)の比が0.13以上、0.5以下に設計することで、より細胞濃縮液中の有核細胞含有濃度(cell/mL)の向上といった効果が得られる。 In the present invention, the ratio of the amount of treated liquid (mL) first passed through the cell separation filter to the total amount of the collected liquid (mL) (the amount of treated recovery liquid (mL) first passed through the cell separation filter) / Total amount of recovered liquid (mL)) is greater than 0 and 0.61 or less. The ratio of the processing volume (mL) of the collected liquid that first passes through the cell separation filter to the total volume (mL) of the recovered liquid (the processing volume of the recovered liquid that first passes through the cell separation filter (mL) / recovered liquid When the total amount (mL) is set to be larger than 0 and 0.61 or less, the cells can be collected more efficiently than simply dividing and introducing the collection solution. In dividing and introducing the collection liquid, the cells can be efficiently collected by reducing the amount of the collection liquid initially introduced. More preferably, the ratio of the treatment volume (mL) of the collected liquid that first passes through the cell separation filter and the total volume (mL) of the collected liquid is designed to be 0.13 or more and 0.5 or less, so that the cells The effect of improving the concentration of nucleated cells (cell / mL) in the concentrate is obtained.
本発明において、回収液の液量について特に制限はないが、回収液の用途に合わせて設計することが好ましく、例えば、回収液を培養に用いる場合は、培養容器の容積に応じて設計すれば良く、回収液を濃縮して治療に用いる場合には、前記細胞含有液の液量よりも少なく設計するか、あるいは点滴バック、注射器又はシリンジ等の容積に合わせて回収液の液量を設計すればよい。 In the present invention, the amount of the recovered liquid is not particularly limited, but is preferably designed according to the use of the recovered liquid. For example, when the recovered liquid is used for culture, it may be designed according to the volume of the culture vessel. If the collected liquid is concentrated for use in therapy, design it to be less than the volume of the cell-containing liquid, or design the volume of the collected liquid according to the volume of the infusion bag, syringe, syringe, etc. That's fine.
また、本発明は前記導入口から細胞含有液を分割して導入する前に、前記導入口からプライミング液を導入し、前記細胞分離フィルターをプライミングする工程を行なってもよい。前記導入口からプライミング液を導入し、プライミングすることで、細胞分離フィルター内の夾雑物や気泡を除去することができるため、より効率的に細胞を捕捉することができる。前記プライミング液は生理食塩水や緩衝液など、細胞に影響を与えない液が挙げられる。 Further, in the present invention, before dividing and introducing the cell-containing solution from the introduction port, a step of priming the cell separation filter by introducing a priming solution from the introduction port may be performed. By introducing a priming solution from the introduction port and performing priming, impurities and bubbles in the cell separation filter can be removed, so that cells can be captured more efficiently. Examples of the priming solution include a solution that does not affect cells, such as physiological saline and a buffer solution.
また、本発明は前記導出口から回収液を分割して導入する前に、前記導入口から洗浄液を導入し、前記細胞分離フィルターを洗浄する工程を行なってもよい。前記導入口から洗浄液を導入し、前記細胞分離フィルターを洗浄することで、フィルター内の夾雑物を除去することができるため、回収液中の夾雑物を低減することができる。 Further, in the present invention, a step of washing the cell separation filter by introducing a washing solution from the introduction port may be performed before the collection solution is divided and introduced from the outlet. By introducing the washing solution from the introduction port and washing the cell separation filter, the impurities in the filter can be removed, so that the impurities in the collected solution can be reduced.
本発明の製造方法は、室温下で行ってもよいし、冷蔵温度下で行ってもよい。冷蔵温度下で行う場合、冷蔵された細胞含有液を導入することが挙げられる。細胞含有液の冷蔵方法としては、冷蔵庫、ウォーターバスまたはドライアイスによる冷蔵等が挙げられる。冷蔵温度としては、1℃以上6℃以下が好ましく、3℃以上5℃以下がより好ましい。 The production method of the present invention may be performed at room temperature or at a refrigeration temperature. When carrying out under refrigeration temperature, introduce | transducing the refrigerated cell containing liquid is mentioned. Examples of the refrigeration method of the cell-containing liquid include refrigeration with a refrigerator, a water bath, or dry ice. The refrigeration temperature is preferably 1 ° C. or higher and 6 ° C. or lower, and more preferably 3 ° C. or higher and 5 ° C. or lower.
本発明で製造された細胞濃縮液は、培養して増殖させてもよいし、治療用途として用いてもよい。具体的な治療用途としては、細胞濃縮液に含まれる有核細胞の治療効果にあわせて用いれば特に限定されないが、例えば、虚血性疾患、血管系疾患が挙げられる。さらに、細胞濃縮液に含まれる有核細胞を、分化誘導剤等によって所望の細胞に分化誘導することで、軟骨損傷、骨疾患、心筋疾患、血管疾患、神経疾患などの患者に移植する細胞として使用することができる。 The cell concentrate produced in the present invention may be cultured and proliferated, or may be used for therapeutic purposes. Although it will not specifically limit if it uses according to the therapeutic effect of the nucleated cell contained in a cell concentrate as a specific therapeutic use, For example, an ischemic disease and a vascular system disease are mentioned. Furthermore, by inducing differentiation of nucleated cells contained in the cell concentrate into desired cells with a differentiation inducer etc., as cells to be transplanted into patients with cartilage damage, bone disease, myocardial disease, vascular disease, neurological disease, etc. Can be used.
前記分化誘導剤としては、細胞を分化誘導できるものを使用することが好ましく、例えば、軟骨への分化誘導剤としてはデキサメタゾン、TGFβ、インシュリン、トランスフェリン、エタノールアミン、プロリン、アスコルビン酸、ピルビン酸塩、セレン等が挙げられ、骨への分化誘導剤としてはデキサメタゾン、β−グリセロリン酸、ビタミンC、アスコルビン酸塩等が挙げられ、心筋への分化誘導剤としてはEGF、PDGF、5−アザシチジン等が挙げられ、神経への分化誘導剤としてはEGF、bFGF、bHLH等が挙げられ、血管への分化誘導剤としてはbFGF、VEGF等が挙げられる。 As the differentiation inducer, those capable of inducing differentiation of cells are preferably used. For example, dexamethasone, TGFβ, insulin, transferrin, ethanolamine, proline, ascorbic acid, pyruvate, Examples include selenium and the like, dexamethasone, β-glycerophosphate, vitamin C, ascorbate and the like as bone differentiation inducers, and EGF, PDGF, 5-azacytidine and the like as myocardial differentiation inducers. Examples of the differentiation-inducing agent for nerves include EGF, bFGF, bHLH and the like, and examples of the differentiation-inducing agent for blood vessels include bFGF, VEGF and the like.
本発明の製造方法より得られた細胞濃縮液、有核細胞及び前記有核細胞を増殖させた細胞集団を凍結保存してもよい。細胞へのダメージを低減させる観点から、液体窒素を用いて凍結保存することが好ましい。なお、凍結保存した細胞は、ヒトや動物への移植、研究への使用、又は再度培養することができる。 You may cryopreserve the cell concentrate obtained by the manufacturing method of this invention, the nucleated cell, and the cell population which expanded the said nucleated cell. From the viewpoint of reducing damage to cells, it is preferable to cryopreserve using liquid nitrogen. The cryopreserved cells can be transplanted into humans and animals, used for research, or cultured again.
本発明の製造方法より得られた細胞濃縮液、有核細胞及び前記有核細胞を増殖させた細胞集団を用いて医薬品組成物も製造することができる。前記細胞濃縮液や細胞集団を薬学的に許容される添加剤と混合することで医薬品組成物を製造することができる。前記薬学的に許容される添加剤としては、凝固剤、ビタミン等の栄養源、抗生物質等が挙げられる。 A pharmaceutical composition can also be produced using the cell concentrate obtained from the production method of the present invention, nucleated cells, and a cell population obtained by growing the nucleated cells. A pharmaceutical composition can be produced by mixing the cell concentrate or cell population with a pharmaceutically acceptable additive. Examples of the pharmaceutically acceptable additive include coagulants, nutrient sources such as vitamins, antibiotics and the like.
以下に、本発明を具体的に説明するために詳細な実施例を挙げるが、本発明はこれらに限定されるものではない。 In the following, detailed examples are given to specifically describe the present invention, but the present invention is not limited thereto.
(実施例1)
直径52mmのポリカーボネート製の円筒状容器に、ポリブチレンテレフタラート製の円形の不織布(細胞分離材)105枚を、積層状態で充填し、上下の開口部にノズル付押え部材を差し込み、その上からキャップでネジ止めし、細胞分離フィルターを作製した。まず生理食塩水50mLを入口側よりシリンジを用いて手押し3回通液した。次にCPD抗凝固の新鮮ウシ血液150mL(CPD:血液=1:4で混合した20%CPDを含むウシ末梢血)を重力落下により導入口より通液した。前記血液の全量である150mLを最初が140mL、残りが10mLとなるように分割して細胞分離フィルターに通液した後、血液の通液とは逆方向から6%ヒドロキシエチルスターチを、それぞれ11.5mLずつシリンジを用いて手押しで流し、合計23mLの回収液を得た。その後、処理前血液の血算、回収した溶液の血算を血球カウンター(シスメックス、K−4500)により測定し、血球細胞の回収率を算出した。試験条件詳細及び結果を表1、2に示す。
Example 1
A cylindrical cylindrical container made of polycarbonate with a diameter of 52 mm is filled with 105 non-woven fabrics (cell separators) made of polybutylene terephthalate in a stacked state, and a pressing member with a nozzle is inserted into the upper and lower openings, and from above A cell separation filter was prepared by screwing with a cap. First, 50 mL of physiological saline was manually passed from the inlet side using a syringe three times. Next, 150 mL of CPD anticoagulated fresh bovine blood (bovine peripheral blood containing 20% CPD mixed at CPD: blood = 1: 4) was passed through the inlet by gravity drop. After dividing 150 mL of the total amount of the blood so that the initial volume is 140 mL and the remaining volume is 10 mL and passing through a cell separation filter, 6% hydroxyethyl starch is added in the opposite direction to the blood flow, respectively. 5 mL each was poured by hand using a syringe to obtain a total of 23 mL of recovered liquid. Thereafter, the blood count of pre-treated blood and the blood count of the collected solution were measured with a blood cell counter (Sysmex, K-4500), and the blood cell recovery rate was calculated. Details of test conditions and results are shown in Tables 1 and 2.
(実施例2)
実施例1と同様にして細胞分離フィルターを作製した。次に実施例1と同様に生理食塩水を3回通液し、CPD抗凝固の新鮮ウシ血液150mL(CPD:血液=1:4で混合した20%CPDを含むウシ末梢血)を全量として、75mLずつ2回に分割し、それぞれ自然落下により導入口より通液した。次に血液の通液とは逆方向から6%ヒドロキシエチルスターチを、それぞれ11.5mLずつシリンジを用いて流し、合計23mLの回収液を得た。その後、処理前血液の血算、回収した溶液の血算を血球カウンター(シスメックス、K−4500)により測定し、血球細胞の回収率を算出した。試験条件詳細及び結果を表1、2に示す。
(Example 2)
A cell separation filter was prepared in the same manner as in Example 1. Next, physiological saline was passed three times in the same manner as in Example 1 and 150 mL of CPD anticoagulated fresh bovine blood (bovine peripheral blood containing 20% CPD mixed at CPD: blood = 1: 4) was taken as the total amount. Each 75 mL was divided into two portions, and each was allowed to flow through the inlet by natural drop. Next, 11.5 mL each of 6% hydroxyethyl starch was flowed from the opposite direction to the blood flow using a syringe to obtain a total of 23 mL of recovered liquid. Thereafter, the blood count of pre-treated blood and the blood count of the collected solution were measured with a blood cell counter (Sysmex, K-4500), and the blood cell recovery rate was calculated. Details of test conditions and results are shown in Tables 1 and 2.
(実施例3)
実施例1と同様にして細胞分離フィルターを作製した。次に実施例1と同様に生理食塩水を3回通液し、CPD抗凝固の新鮮ウシ血液150mL(CPD:血液=1:4で混合した20%CPDを含むウシ末梢血)を全量として、75mLずつ2回に分割し、それぞれ自然落下により導入口より通液した。次に血液の通液とは逆方向から6%ヒドロキシエチルスターチを、最初を3mL、残りを20mLとなるようにそれぞれ分割して流し、合計23mLの回収液を得た。その後、処理前血液の血算、回収した溶液の血算を血球カウンター(シスメックス、K−4500)により測定し、血球細胞の回収率を算出した。試験条件詳細及び結果を表1、2に示す。
(Example 3)
A cell separation filter was prepared in the same manner as in Example 1. Next, physiological saline was passed three times in the same manner as in Example 1 and 150 mL of CPD anticoagulated fresh bovine blood (bovine peripheral blood containing 20% CPD mixed at CPD: blood = 1: 4) was taken as the total amount. Each 75 mL was divided into two portions, and each was allowed to flow through the inlet by natural drop. Next, 6% hydroxyethyl starch was divided and flowed in the opposite direction to the blood flow so that the first was 3 mL and the remaining was 20 mL to obtain a total of 23 mL of recovered liquid. Thereafter, the blood count of pre-treated blood and the blood count of the collected solution were measured with a blood cell counter (Sysmex, K-4500), and the blood cell recovery rate was calculated. Details of test conditions and results are shown in Tables 1 and 2.
(比較例1)
実施例1と同様にして細胞分離フィルターを作製し、生理食塩水を3回通液した。その後CPD抗凝固の新鮮ウシ血液150mL(CPD:血液=1:4で混合した20%CPDを含むウシ末梢血)を全量として、全量を分割せずに自然落下により導入口より通液した。次に血液の通液とは逆方向から6%ヒドロキシエチルスターチを分割せずに全量の23mLを流した。その後、処理前血液の血算、回収した溶液の血算を血球カウンター(シスメックス、K−4500)により測定し、血球細胞の回収率を算出した。試験条件詳細及び結果を表1、2に示す。
(Comparative Example 1)
A cell separation filter was prepared in the same manner as in Example 1, and physiological saline was passed three times. Thereafter, 150 mL of CPD anticoagulated fresh bovine blood (bovine peripheral blood containing 20% CPD mixed at CPD: blood = 1: 4) was made into a total amount, and the whole amount was passed through the inlet through natural falling without being divided. Next, a total volume of 23 mL was flowed without dividing 6% hydroxyethyl starch from the opposite direction of blood flow. Thereafter, the blood count of pre-treated blood and the blood count of the collected solution were measured with a blood cell counter (Sysmex, K-4500), and the blood cell recovery rate was calculated. Details of test conditions and results are shown in Tables 1 and 2.
(比較例2)
実施例1と同様にして細胞分離フィルターを作製し、生理食塩水を3回通液した。その後CPD抗凝固の新鮮ウシ血液150mL(CPD:血液=1:4で混合した20%CPDを含むウシ末梢血)を全量として、75mLずつ2回に分割し、それぞれ自然落下により導入口より通液した。次に血液の通液とは逆方向から6%ヒドロキシエチルスターチを分割せずに全量の23mL流した。その後、処理前血液の血算、回収した溶液の血算を血球カウンター(シスメックス、K−4500)により測定し、血球細胞の回収率を算出した。試験条件詳細及び結果を表1、2に示す。
(Comparative Example 2)
A cell separation filter was prepared in the same manner as in Example 1, and physiological saline was passed three times. Then, 150 mL of fresh CPD anticoagulated bovine blood (bovine peripheral blood containing 20% CPD mixed with CPD: blood = 1: 4) was divided into 75 mL portions in two portions, and each was passed through the inlet by natural fall. did. Next, 23% of the total amount was allowed to flow without dividing 6% hydroxyethyl starch from the opposite direction to the blood flow. Thereafter, the blood count of pre-treated blood and the blood count of the collected solution were measured with a blood cell counter (Sysmex, K-4500), and the blood cell recovery rate was calculated. Details of test conditions and results are shown in Tables 1 and 2.
(実施例4)
直径30mmのポリカーボネート製の円筒状容器に、レーヨン製の円形の不織布(細胞分離材)36枚を積層状態で充填し、ノズル、及び直径26mmの押さえ込み部材にて不織布を固定した細胞分離フィルターを作製した。生理食塩水30mLを導入口側より通液し、ヘパリンにより抗凝固した新鮮ブタ骨髄液合計60mL(ヘパリン50単位)を全量として、自然落下により導入口より30mLずつ2回に分割して通液した。次に骨髄液の通液と同方向からそれぞれ15mLの生理食塩水を流して洗浄し、その後それぞれ25mLずつのDMEM培地を骨髄液の通液とは逆方向から流し、合計50mLの回収液を得た。回収液をポリスチレン製シャーレ(直径10cm、IWAKI社)に移し、37℃、CO2インキュベーター内で培養を行った。2〜3日ごとに培地交換し、培養開始9日後にクリスタルバイオレットでコロニーを染色して出現したコロニー数を測定した。出現したコロニー数より間葉系幹細胞の総数を求めた。試験条件及び結果を表3及び4に示す。
Example 4
A cylindrical container made of polycarbonate with a diameter of 30 mm is filled with 36 rayon circular nonwoven fabrics (cell separation materials) in a laminated state, and a cell separation filter is produced in which the nonwoven fabric is fixed with a nozzle and a pressing member with a diameter of 26 mm. did. 30 mL of physiological saline was passed through the inlet side, and a total of 60 mL (50 units of heparin) of fresh porcine bone marrow anticoagulated with heparin was divided into two 30 mL portions from the inlet by natural fall. . Next, wash with 15 mL of physiological saline in the same direction as the bone marrow fluid flow, and then wash each 25 mL of DMEM medium in the opposite direction to the bone marrow fluid flow to obtain a total of 50 mL of recovered solution. It was. The collected liquid was transferred to a petri dish made of polystyrene (diameter 10 cm, IWAKI) and cultured in a CO 2 incubator at 37 ° C. The medium was changed every 2 to 3 days, and the number of colonies that appeared after staining colonies with crystal violet was measured 9 days after the start of the culture. The total number of mesenchymal stem cells was determined from the number of colonies that appeared. Test conditions and results are shown in Tables 3 and 4.
(比較例3)
実施例4と同様にして細胞分離フィルターを作製した。生理食塩水を導入口側より通液し、ヘパリンにより抗凝固した新鮮ブタ骨髄液60mL(ヘパリン50単位)を分割せずに自然落下により導入口より通液した。その後、骨髄液の通液と同方向からそれぞれ15mLの生理食塩水を流して洗浄し、分割せずに50mLのDMEM培地を骨髄液の通液した方向とは逆方向から流すことで回収液を得た。実施例4と同様の方法で回収できた総間葉系幹細胞(MSC)数をコロニー出現数より求めた。試験条件及び結果を表3及び4に示す。
(Comparative Example 3)
A cell separation filter was produced in the same manner as in Example 4. Saline was passed through the inlet side, and 60 mL of fresh porcine bone marrow fluid (heparin 50 units) anticoagulated with heparin was passed through the inlet port by natural falling without being divided. Then, 15 mL of physiological saline is flowed in the same direction as the flow of bone marrow fluid and washed, and 50 mL of DMEM medium is flowed in the direction opposite to the direction of bone marrow fluid flow without being divided. Obtained. The total number of mesenchymal stem cells (MSC) recovered by the same method as in Example 4 was determined from the number of appearance of colonies. Test conditions and results are shown in Tables 3 and 4.
実施例1〜3では、接着性を有する有核細胞の回収率は68%〜72%、接着性の弱い赤血球の回収率は12%〜13%となった。一方、比較例1、2では、赤血球の回収率は10%〜13%とほぼ変わらないものの、有核細胞回収率は60%〜62%と低い収率になった。実施例4では、回収液中の間葉系幹細胞(MSC)の総数は2160CFUとなった。一方、比較例3では、間葉系幹細胞の総数が1380CFUとなり、収率の低下が見られた。赤血球の収率に関しては両者とも差はほぼなかった。したがって、血液もしくは骨髄液、及び回収液をそれぞれある一定の割合で分割して導入した際に、特に治療効果の高い接着性を有する細胞をより効率良く回収・濃縮できる効果があることがわかる。 In Examples 1 to 3, the recovery rate of nucleated cells having adhesiveness was 68% to 72%, and the recovery rate of red blood cells having weak adhesiveness was 12% to 13%. On the other hand, in Comparative Examples 1 and 2, the recovery rate of erythrocytes was almost unchanged from 10% to 13%, but the recovery rate of nucleated cells was as low as 60% to 62%. In Example 4, the total number of mesenchymal stem cells (MSC) in the collected liquid was 2160 CFU. On the other hand, in Comparative Example 3, the total number of mesenchymal stem cells was 1380 CFU, and a decrease in yield was observed. There was almost no difference in the yield of erythrocytes. Therefore, it can be seen that when blood or bone marrow fluid and the collected solution are divided and introduced at a certain ratio, cells having particularly high therapeutic effects can be collected and concentrated more efficiently.
上述とおり、本発明の製造方法を用いることで、処理できる細胞含有液量及び回収できる有核細胞数が増加し、それに伴って細胞濃度も増加するため、最終的に用いる細胞濃縮液の質の向上が期待できる。 As described above, by using the production method of the present invention, the amount of cell-containing liquid that can be treated and the number of nucleated cells that can be recovered increase, and the cell concentration also increases accordingly. Improvement can be expected.
Claims (8)
前記導入口から前記細胞含有液を分割して導入し、前記細胞分離フィルターに細胞を捕捉させた後、前記導出口から回収液を分割して導入し、前記細胞濃縮液を前記細胞分離フィルターから回収する工程を有し、且つ、最初に前記細胞分離フィルターに通液する細胞含有液の処理量(mL)と細胞含有液の全量(mL)の比(最初に前記細胞分離フィルターに通液する細胞含有液の処理量(mL)/細胞含有液の全量(mL))が、0.5以上、1未満であることを特徴とする方法。 A method for producing a cell concentrate from a cell-containing solution using a cell separation filter having an inlet and an outlet,
The cell-containing liquid is divided and introduced from the inlet, and after the cells are captured by the cell separation filter, the recovered liquid is divided and introduced from the outlet, and the cell concentrate is removed from the cell separation filter. A ratio of the treatment amount (mL) of the cell-containing solution that first passes through the cell separation filter and the total amount (mL) of the cell-containing solution (mL) that passes through the cell separation filter A method wherein the treatment amount of the cell-containing solution (mL) / total amount of the cell-containing solution (mL)) is 0.5 or more and less than 1.
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