JP2013005789A - Expandable temperature-responsive base material, method for production thereof, and method for use thereof - Google Patents
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Abstract
Description
本発明は生物学、医学分野における有用な培養基材に関するものである。 The present invention relates to a culture substrate useful in the fields of biology and medicine.
今日、動物細胞培養技術が著しく進歩し、動物細胞を対象とした研究開発もさまざまな分野に広がって実施されるようになってきた。対象となる動物細胞の使われ方も、開発当初の細胞そのものを製品化したり、その産生物を製品化するだけでなく、今や細胞やその表層蛋白質を分析することで有用な医薬品を設計したり、患者本人の細胞を生体外で増殖させたり、或いはその細胞の機能を高めて生体内へ戻し治療することも実施されつつある。現在、動物細胞を培養する技術は、多くの研究者が注目している一分野であり、特に生体の組織や臓器構造に類似した細胞の配向構造や機能が反映された細胞培養方法は、医薬品設計の評価のみならず生体組織構築技術としても非常に注目されている。 Today, animal cell culture technology has made significant progress, and research and development on animal cells has been extended to various fields. The target animal cells can be used not only to commercialize the original cells, but also to produce useful products by analyzing the cells and their surface proteins. In addition, the patient's own cells are being grown in vitro, or the function of the cells is increased and returned to the living body for treatment. Currently, the technology for culturing animal cells is one field that many researchers are paying attention to. Cell culture methods that reflect cell orientation structures and functions that are similar to biological tissues and organ structures are In addition to design evaluation, it is attracting a great deal of attention as a living tissue construction technique.
ヒト細胞を含め動物細胞の多くは付着依存性のものである。すなわち、動物細胞を生体外で培養しようとするときは、それらを一度、どこかに付着させる必要性がある。そのような背景のもと、以前より多くの研究者らによって細胞にとってより好ましい基材表面の設計、考案がなされてきたが、これらの技術は何れも細胞培養時に関係するものばかりであった。付着依存性の培養細胞は何かに付着する際、自ら接着性蛋白質を産生する。従ってその細胞を剥離させるときには、従来技術ではその接着性蛋白質を破壊しなければならず、通常酵素処理が行われる。その際、細胞が培養中に産生した各種細胞固有の細胞表層蛋白も同時に破壊されてしまうという重大な課題であった。 Many animal cells, including human cells, are adhesion-dependent. That is, when cultivating animal cells in vitro, it is necessary to attach them once somewhere. Against this background, more and more researchers have designed and devised a substrate surface that is more favorable for cells than before. However, all of these techniques are related to cell culture. When an adhesion-dependent cultured cell attaches to something, it produces an adhesive protein by itself. Therefore, when the cells are detached, the adhesive protein must be destroyed in the prior art, and usually an enzyme treatment is performed. At that time, it was a serious problem that the cell surface proteins inherent to various cells produced during culturing of the cells were destroyed at the same time.
このような背景のもと、特許文献1には、水に対する上限若しくは下限臨界溶解温度が0〜80℃であるポリマーで基材表面を被覆した細胞培養支持体上にて、細胞を上限臨界溶解温度以下または下限臨界溶解温度以上で培養し、その後上限臨界溶解温度以上または下限臨界溶解温度以下にすることにより酵素処理なくして培養細胞を剥離させる新規な細胞培養法が記載されている。また、特許文献2には、この温度応答性細胞培養基材を利用して皮膚細胞を上限臨界溶解温度以下或いは下限臨界溶解温度以上で培養し、その後上限臨界溶解温度以上或いは下限臨界溶解温度以下にすることにより培養皮膚細胞を低損傷で剥離させることが記載されている。さらに、特許文献3には、この温度応答性細胞培養基材を用いて培養細胞の表層蛋白質の修復方法が記載されている。温度応答性細胞培養基材を利用することにより、従来の培養技術に対しさまざまな新規な展開をはかれるようになってきた。 Against this background,
細胞が細胞培養基材表面に接着、伸展、増殖する場合、細胞外マトリックスなどのような接着タンパク質の吸着を介して、細胞が接着することが知られている。非特許文献1では、膵島由来の細胞が温度応答性細胞培養表面に接着、増殖するためには特定の細胞外マトリックスの吸着が必要であることが示されている。また、非特許文献2では、ある細胞が材料表面に接着するには、材料表面の接触角を適度にすることが需要であり、良好な接着を実現するには、細胞種によって、その適度な接触角が異なることが示されている。これらの文献は温度応答性細胞培養表面に目的とする臓器、組織由来の細胞を接着、増殖させるには血清中に含まれる、特定の細胞外マトリクスの吸着が必要であり、目的の細胞種を接着、増殖させるには適当な温度応答性細胞培養表面の設計が重要であることが示されている。 It is known that when a cell adheres, spreads and grows on the surface of a cell culture substrate, the cell adheres via adsorption of an adhesion protein such as an extracellular matrix. Non-Patent
非特許文献3および非特許文献4では、温度応答性ポリマー層の厚みやポリマー密度が、温度応答性細胞培養基材の表面濡れ性、細胞外マトリックスの吸着量、細胞接着性に大きな影響を与えることが示されている。これらの結果文献から、特定の細胞を温度応答性細胞培養表面に接着させるためには、培養する細胞の種類に応じ、温度応答性細胞培養表面の濡れ性、吸着させる細胞外マトリックス種類やその吸着量の最適化が必要であり、その最適化には温度応答性細胞培養基材の温度応答性ポリマーの厚みや固定化密度の制御が必要であることは周知されている。 In Non-Patent Document 3 and Non-Patent Document 4, the thickness and polymer density of the temperature-responsive polymer layer greatly affect the surface wettability of the temperature-responsive cell culture substrate, the amount of adsorption of the extracellular matrix, and the cell adhesion. It has been shown. Based on these results, in order to adhere specific cells to the temperature-responsive cell culture surface, the wettability of the temperature-responsive cell culture surface, the type of extracellular matrix to be adsorbed, and its adsorption, depending on the type of cell to be cultured It is well known that the amount needs to be optimized, and that optimization requires control of the thickness and immobilization density of the temperature-responsive polymer of the temperature-responsive cell culture substrate.
これまで、製造条件を変化させること温度応答性ポリマー膜厚層あるは温度応答性ポリマー固定化密度を個別に変化させることは可能であったが、ナノオーダーレベルで段階的にポリマー膜厚を変化させたり、数マイクログラム/cm2でのポリマー固定化密度を同時に変化させるとは非常に困難であった。温度応答性ポリマー薄膜の厚みや密度を同時に制御し、同時に温度応答性細胞培養表面の細胞接着性や物性を制御する技術はこれまで報告がない。生体由来の細胞が有する多様かつ複雑な物性を有する細胞を温度応答性細胞培養表面上で培養し剥離するには、固定化した温度応答性ポリマーの膜厚、ポリマー密度を制御する技術が強く求められていた。Previously, it was possible to change the temperature-responsive polymer film thickness layer or the temperature-responsive polymer immobilization density individually by changing the manufacturing conditions, but the polymer film thickness was changed step by step at the nano-order level. It was very difficult to change the polymer immobilization density at several micrograms / cm 2 at the same time. There has been no report on a technique for simultaneously controlling the thickness and density of a temperature-responsive polymer thin film and simultaneously controlling the cell adhesion and physical properties of the temperature-responsive cell culture surface. In order to cultivate cells with various and complex physical properties, which are derived from living cells, on the temperature-responsive cell culture surface, there is a strong demand for technology to control the film thickness and polymer density of the immobilized temperature-responsive polymer. It was done.
本発明は、温度応答性基材表面へ伸縮という物理的な負荷を与えることで、その表面に被覆される温度応答性ポリマー層の状態を制御することで細胞の接着性および剥離性を制御できる温度応答性細胞培養基材、その製造方法及びその利用方法の提供を目的とする。 The present invention can control the adhesiveness and detachability of cells by controlling the state of the temperature-responsive polymer layer coated on the surface by applying a physical load of stretching to the surface of the temperature-responsive substrate. An object of the present invention is to provide a temperature-responsive cell culture substrate, a production method thereof, and a utilization method thereof.
本発明者らは上記課題を解決するために、種々の角度から検討を加えて、研究開発を行った。その結果、驚くべくことに、温度応答性ポリマーを伸縮性を有する基材表面に化学的に固定化することで、得られた温度応答性ポリマー固定化基材を伸張、収縮させることで、基材表面の温度応答性ポリマー層の状態を変えられ、細胞の接着性および剥離性を変えられることが分かった。本発明はかかる知見に基づいて完成されたものである。 In order to solve the above problems, the present inventors have studied and developed from various angles. As a result, surprisingly, by thermally immobilizing the temperature-responsive polymer on the surface of the stretchable substrate, the resulting temperature-responsive polymer-immobilized substrate is stretched and contracted. It was found that the state of the temperature-responsive polymer layer on the surface of the material can be changed, and the cell adhesion and peelability can be changed. The present invention has been completed based on such findings.
すなわち、本発明は、基材表面に0〜80℃の温度範囲内で水和力が変化する温度応答性ポリマーが被覆され、当該表面を延伸及び/又は収縮させることで生体材料との親和性を変えられる、温度応答性基材を提供する。また、本発明は伸縮性能を有する基材の表面へ0〜80℃の範囲で水に対する相互作用が変化する温度応答性ポリマー層を形成させるモノマー、オリゴマー、ポリマーの少なくとも1種以上が含まれる溶液を塗布し、その後、当該基材表面全体に温度応答性ポリマー層を形成させる、温度応答性基材の製造方法を提供する。さらに、本発明はこうして得られた温度応答性基材の利用方法を提供するものである。 That is, in the present invention, the base material surface is coated with a temperature-responsive polymer whose hydration power changes within a temperature range of 0 to 80 ° C., and the surface is stretched and / or contracted, thereby affinity with a biomaterial. A temperature-responsive substrate is provided. In addition, the present invention provides a solution containing at least one of a monomer, an oligomer, and a polymer that forms a temperature-responsive polymer layer whose interaction with water changes in the range of 0 to 80 ° C. on the surface of a base material having stretchability. Is provided, and then a temperature-responsive polymer layer is formed on the entire surface of the substrate. Furthermore, this invention provides the utilization method of the temperature-responsive base material obtained in this way.
本発明であれば、温度応答性ポリマーを被覆した1種類の基材を準備し、その基材を伸縮することで生体材料との親和性を変えられ、多様な用途への展開をはかれるようになる。本発明は世界に類のない新規な発想による極めて重要な発明と考えている。 According to the present invention, one kind of base material coated with a temperature-responsive polymer is prepared, and the affinity with the biomaterial can be changed by expanding and contracting the base material, so that it can be developed for various uses. Become. The present invention is considered to be a very important invention based on a novel idea unparalleled in the world.
本発明とは、伸縮性基材表面に0〜80℃の温度範囲内で水和力が変化する温度応答性ポリマーが被覆され、当該表面を延伸及び/又は収縮させることで生体材料との親和性を変えられる、温度応答性基材に関するものである。これまでに、基材表面の温度応答性ポリマー層を特定の状態にすることによって細胞が付着する場合と付着しない場合があること、また基材の環境温度を変えるだけでそれまで付着し増殖していた細胞が剥離すること等が分かっている。本発明はこれらの知見を生かし、温度応答性基材表面を物理的に伸縮させることで1種類の温度応答性培養基材からさまざまな状態の表面とし、その結果として細胞等の生体材料の付着、脱離をはかり、生体材料の分離、精製、濃縮、あるいは細胞シートの作製等の広範囲な用途へ応用展開をはかろうとするものである。 The present invention means that a stretchable substrate surface is coated with a temperature-responsive polymer whose hydration power changes within a temperature range of 0 to 80 ° C., and the surface is stretched and / or shrunk so as to have an affinity for a biomaterial. The present invention relates to a temperature-responsive substrate that can change its properties. Until now, cells may or may not adhere by making the temperature-responsive polymer layer on the substrate surface in a specific state, and by simply changing the environmental temperature of the substrate, it will adhere and proliferate until then. It is known that the cells that had been peeled off. The present invention makes use of these findings to physically expand and contract the surface of the temperature-responsive substrate, thereby changing the surface of the various states from one type of temperature-responsive culture substrate, and as a result, the attachment of biological materials such as cells. It is intended to be applied to a wide range of uses such as separation, purification, concentration, and preparation of cell sheets by measuring detachment.
本発明で用いられる生体材料とは生体由来のものであれば特に限定されないが、例えばタンパク質、抗体、糖タンパク質、ペプチド、多糖類、核酸等の生理活性物質、細胞、組織、菌等が挙げられるが特に限定されるものではない。その中で細胞について具体的に示すと、使用される細胞は動物細胞であれば良く、その入手先、作製方法は特に限定されるものではない。本発明の細胞は、例えば、動物、昆虫、植物等の細胞、細菌類が挙げられる。特に、動物細胞の由来として、ヒト、サル、イヌ、ネコ、ウサギ、ラット、ヌードマウス、マウス、モルモット、ブタ、ヒツジ、チャイニーズハムスター、ウシ、マーモセット、アフリカミドリザル等が挙げられるが特に限定されるものではない。また、本発明で用いる培地は、動物細胞を培養する培地であれば特に限定されないが、例えば、無血清培地、血清含有培地等が挙げられる。そのような培地は、さらにレチノイン酸、アスコルビン酸等の分化誘導物質を添加しても良い。基材表面への播種密度は常法に従えば良く特に限定されるものではない。 The biomaterial used in the present invention is not particularly limited as long as it is derived from a living body, and examples thereof include physiologically active substances such as proteins, antibodies, glycoproteins, peptides, polysaccharides, and nucleic acids, cells, tissues, and fungi. Is not particularly limited. Specifically, the cells used here may be animal cells, and the source and production method thereof are not particularly limited. Examples of the cell of the present invention include cells such as animals, insects and plants, and bacteria. In particular, examples of animal cell origin include humans, monkeys, dogs, cats, rabbits, rats, nude mice, mice, guinea pigs, pigs, sheep, Chinese hamsters, cattle, marmoset, African green monkeys, etc. is not. The medium used in the present invention is not particularly limited as long as it is a medium for culturing animal cells, and examples thereof include a serum-free medium and a serum-containing medium. Such a medium may further contain a differentiation inducer such as retinoic acid or ascorbic acid. The seeding density on the substrate surface is not particularly limited as long as it follows a conventional method.
本発明で用いられる伸縮性基材とは、物理的に変形なく可逆的に伸縮できるものであれば特に限定されるものではないが、例えば、ポリジメチルシロキサン、ポリウレタン、ゴム及びこれらの各種誘導体が挙げられる。本発明では、これらを単独で用いても良く、2種以上を組み合わせて良く、何ら限定されるものではない。その中で、ポリジメチルシロキサンについて具体的に示すと、本発明ではポリジメチルシロキサンとして市販のシリコン膜、シリコンシート、シリコン製板等が挙げられる。その際、末端がアミノプロピル基、カロボキシプロピル基、水酸基で修飾されたポリジメチルシロキサン、或いはアミノ基、カルボキシル基、水酸基、チオール基などの官能基を含むシロキサン、ポリシロキサン化合物を利用し、予め目的とする官能基を含んだポリジメチルシロキサン構造体を作製し利用することでもできる。本発明で用いられる伸縮性基材の伸縮能については特に限定されるものでないが、延伸前を0とした場合に、5〜100%延伸できるものが好ましく、より好ましくは10〜90%延伸できるものが良く、さらに好ましくは15〜80%延伸できるものが良く、最も好ましくは20〜60%延伸できるものが良い。5%より長く延伸できない基材の場合、本発明で示すところの基材表面を伸縮することでさまざまな状態の温度応答性表面を作製することができず好ましくない。 The stretchable substrate used in the present invention is not particularly limited as long as it can be reversibly stretched without being physically deformed. For example, polydimethylsiloxane, polyurethane, rubber, and various derivatives thereof can be used. Can be mentioned. In this invention, these may be used independently and 2 or more types may be combined and it is not limited at all. Among them, specific examples of polydimethylsiloxane include a commercially available silicon film, silicon sheet, silicon plate and the like as polydimethylsiloxane in the present invention. At that time, using a polydimethylsiloxane whose terminal is modified with an aminopropyl group, a carboxoxypropyl group or a hydroxyl group, or a siloxane or polysiloxane compound containing a functional group such as an amino group, a carboxyl group, a hydroxyl group or a thiol group, It is also possible to prepare and use a polydimethylsiloxane structure containing a target functional group in advance. The stretchability of the stretchable substrate used in the present invention is not particularly limited. However, when the stretchable substrate is 0, it is preferably stretchable by 5 to 100%, more preferably stretchable by 10 to 90%. Those that can be stretched by 15 to 80% are more preferable, and those that can be stretched by 20 to 60% are most preferable. In the case of a base material that cannot be stretched for more than 5%, it is not preferable because a temperature-responsive surface in various states cannot be produced by stretching the base material surface shown in the present invention.
本発明に用いる温度応答性ポリマーはホモポリマー、コポリマーのいずれであってもよい。このようなポリマーとしては、例えば、特開平2−211865号公報に記載されているポリマーが挙げられる。具体的には、例えば、以下のモノマーの単独重合または共重合によって得られる。使用し得るモノマーとしては、例えば、(メタ)アクリルアミド化合物、N−(若しくはN,N−ジ)アルキル置換(メタ)アクリルアミド誘導体、またはビニルエーテル誘導体が挙げられ、コポリマーの場合は、これらの中で任意の2種以上を使用することができる。更には、上記モノマー以外のモノマー類との共重合、ポリマー同士のグラフトまたは共重合、あるいはポリマー、コポリマーの混合物を用いてもよい。また、ポリマー本来の性質を損なわない範囲で架橋することも可能である。その際、培養、剥離されるものが細胞であることから、分離が5℃〜50℃の範囲で行われるため、温度応答性ポリマーとしては、ポリ−N−n−プロピルアクリルアミド(単独重合体の下限臨界溶解温度21℃)、ポリ−N−n−プロピルメタクリルアミド(同27℃)、ポリ−N−イソプロピルアクリルアミド(同32℃)、ポリ−N−イソプロピルメタクリルアミド(同43℃)、ポリ−N−シクロプロピルアクリルアミド(同45℃)、ポリ−N−エトキシエチルアクリルアミド(同約35℃)、ポリ−N−エトキシエチルメタクリルアミド(同約45℃)、ポリ−N−テトラヒドロフルフリルアクリルアミド(同約28℃)、ポリ−N−テトラヒドロフルフリルメタクリルアミド(同約35℃)、ポリ−N,N−エチルメチルアクリルアミド(同56℃)、ポリ−N,N−ジエチルアクリルアミド(同32℃)、ポリ(N−(N’−プロピルカルバミド)プロピル(メタ)アクリルアミド(同18〜28℃)などが挙げられる。本発明に用いられる共重合のためのモノマーとしては、ポリアクリルアミド、ポリ−N、N−ジエチルアクリルアミド、ポリ−N、N−ジメチルアクリルアミド、ポリエチレンオキシド、ポリアクリル酸及びその塩、ポリヒドロキシエチルメタクリレート、ポリヒドロキシエチルアクリレート、ポリビニルアルコール、ポリビニルピロリドン、セルロース、カルボキシメチルセルロースなどの含水ポリマーなどが挙げられるが、特に制約されるものではない。 The temperature-responsive polymer used in the present invention may be either a homopolymer or a copolymer. Examples of such a polymer include polymers described in JP-A-2-21865. Specifically, for example, it can be obtained by homopolymerization or copolymerization of the following monomers. Examples of the monomer that can be used include a (meth) acrylamide compound, an N- (or N, N-di) alkyl-substituted (meth) acrylamide derivative, or a vinyl ether derivative. Two or more of these can be used. Furthermore, copolymerization with monomers other than the above monomers, grafting or copolymerization of polymers, or a mixture of polymers and copolymers may be used. Moreover, it is also possible to crosslink within a range that does not impair the original properties of the polymer. In this case, since the cells to be cultured and peeled are cells, separation is performed in the range of 5 ° C. to 50 ° C., and as the temperature-responsive polymer, poly-Nn-propylacrylamide (of a homopolymer) Lower critical solution temperature 21 ° C), poly-Nn-propylmethacrylamide (27 ° C), poly-N-isopropylacrylamide (32 ° C), poly-N-isopropylmethacrylamide (43 ° C), poly- N-cyclopropylacrylamide (at 45 ° C), poly-N-ethoxyethylacrylamide (at about 35 ° C), poly-N-ethoxyethylmethacrylamide (at about 45 ° C), poly-N-tetrahydrofurfurylacrylamide (at the same) About 28 ° C.), poly-N-tetrahydrofurfuryl methacrylamide (about 35 ° C.), poly-N, N-ethylmethyl acetate Luamide (56 ° C.), poly-N, N-diethylacrylamide (32 ° C.), poly (N- (N′-propylcarbamido) propyl (meth) acrylamide (18-28 ° C.), and the like. Monomers for copolymerization used in the invention include polyacrylamide, poly-N, N-diethylacrylamide, poly-N, N-dimethylacrylamide, polyethylene oxide, polyacrylic acid and salts thereof, polyhydroxyethyl methacrylate, poly Hydrous polymers such as hydroxyethyl acrylate, polyvinyl alcohol, polyvinyl pyrrolidone, cellulose, carboxymethyl cellulose, and the like can be mentioned, but are not particularly limited.
上述の場合、上述の各ポリマーの基材表面への被覆方法は、特に制限されないが、例えば、基材と上記モノマーまたはポリマーを、電子線照射(EB)、γ線照射、紫外線照射、プラズマ処理、コロナ処理、有機重合反応のいずれかにより、または塗布、混練等の物理的吸着等により行うことができる。その中で、伸縮性基材としてポリジメチルシロキサンを選んだ場合、そのものへの温度応答性ポリマーの固定化方法として、ポリジメチルシロキサンを含む構造体表面にプラズマ処理、塩酸処理、UV処理を行い、親水性化処理を行なった後、アミノ基、カルボキシル基、チオール基などの親水性官能基を含む有機系化合物あるいは無機系化合物を水系溶媒中でポリジメチルシロキサン構造体表面と反応させ、これらの親水性官能基を表面あるいは界面近傍に導入する方法が挙げられるが特に限定されるものではない。その際、モノマー溶液を0.5wt%〜70wt%で溶媒に溶解させた溶液を親水性官能基で修飾したポリジメチルシラン表面に塗布し、電子線照射重合により温度応答性ポリマーを固定化させても良い。親水性官能基を含む有機系化合物としては、ポリアリルアミン、ポリエチレンイミン、ポルアクリル酸、3−アミノプロピルメタクリルアミドなどが挙げられる。親水性官能基を含む無機系化合物として、アミノプロピルトリエトキシシラン、3−アミノプロピルトリメトキシシラン、(3−メルカプトプロピル)トリメトキシシラン、(3−メルカプトプロピル)トリエトキシシラン、カルボキシエチルシラントリオールを挙げられる。これらの化合物をポリジメチルシロキサンを含む構造体表面の導入する際、溶媒として水あるいは水と有機溶媒の混合溶液が望ましく、混合溶液の場合、有機溶媒の水に対する比率が1wt%〜50wt%が望ましい。混合する有機溶媒はアセトン、酢酸、メタノール、エタノールなどのアルコール系溶媒が好適である。 In the case described above, the method for coating the surface of each polymer described above is not particularly limited. For example, the substrate and the monomer or polymer are irradiated with electron beam (EB), γ-ray irradiation, ultraviolet irradiation, plasma treatment. , Corona treatment, organic polymerization reaction, or physical adsorption such as coating and kneading. Among them, when polydimethylsiloxane is selected as the stretchable substrate, the surface of the structure containing polydimethylsiloxane is subjected to plasma treatment, hydrochloric acid treatment, and UV treatment as a method for fixing the temperature-responsive polymer to itself. After the hydrophilization treatment, an organic compound or inorganic compound containing a hydrophilic functional group such as an amino group, a carboxyl group, or a thiol group is reacted with the surface of the polydimethylsiloxane structure in an aqueous solvent. Although the method of introduce | transducing a functional functional group into the surface or interface vicinity is mentioned, it does not specifically limit. At that time, a solution obtained by dissolving a monomer solution in a solvent at 0.5 wt% to 70 wt% is applied to the surface of polydimethylsilane modified with a hydrophilic functional group, and the temperature-responsive polymer is immobilized by electron beam irradiation polymerization. Also good. Examples of the organic compound containing a hydrophilic functional group include polyallylamine, polyethyleneimine, poracrylic acid, and 3-aminopropylmethacrylamide. As an inorganic compound containing a hydrophilic functional group, aminopropyltriethoxysilane, 3-aminopropyltrimethoxysilane, (3-mercaptopropyl) trimethoxysilane, (3-mercaptopropyl) triethoxysilane, and carboxyethylsilanetriol are used. Can be mentioned. When introducing these compounds into the surface of the structure containing polydimethylsiloxane, water or a mixed solution of water and an organic solvent is desirable as a solvent, and in the case of a mixed solution, the ratio of the organic solvent to water is desirably 1 wt% to 50 wt%. . The organic solvent to be mixed is preferably an alcohol solvent such as acetone, acetic acid, methanol, and ethanol.
本発明とは、上記伸縮性基材表面に0〜80℃の温度範囲内で水和力が変化する上記温度応答性ポリマーが被覆されたものであり、その基材表面を延伸及び/又は収縮させることで生体材料との親和性を変え、さまざまな用途に展開しようとするものである。このことを実現するためには、上述した生体材料が、まず、本発明の温度応答性基材表面に付着することが必須となる。その生体材料が付着する際の基材表面の条件は、その基材表面に負荷が掛かって延伸、もしくは収縮されていても良く、何ら負荷が掛かっていなくても良く、いずれにせよそのいずれかの負荷状態で、基材表面への温度応答性ポリマーの被覆量が、0.6〜2.5μg/cm2の範囲であることが良く、好ましくは1.1〜2.3μg/cm2の範囲であることが良く、さらに好ましくは1.3〜2.0μg/cm2の範囲であることが良く、最も好ましくは1.5〜1.8μg/cm2の範囲であることが良い。0.6μg/cm2より少ない被覆量のとき、刺激を与えても当該ポリマー上の生体材料は剥離し難く、作業効率が著しく悪くなり好ましくない。逆に2.5μg/cm2以上であると、その領域に生体材料が付着し難く、生体材料を十分に付着させることが困難となる。このような場合、温度応答性ポリマー被覆層の上にさらにタンパク質を被覆すれば、基材表面の温度応答性ポリマー被覆量は2.3μg/cm2以上であっても良く、その際の温度応答性ポリマーの被覆量は9.0μg/cm2以下が良く、好ましくは8.0μg/cm2以下が良く、7.0μg/cm2以下が好都合である。温度応答性ポリマーの被覆量が9.0μg/cm2以上であると温度応答性ポリマー被覆層の上にさらに細胞接着性タンパク質を被覆しても生体材料が付着し難くなり好ましくない。そのような細胞接着性タンパク質の種類は何ら限定されるものではないが、例えば、コラーゲン、ラミニン、ラミニン5、マトリゲル等の単独、もしくは2種以上の混合物が挙げられる。また、これらの細胞接着性タンパク質の被覆方法は常法に従えば良く、通常、生体材料接着性タンパク質の水溶液を基材表面に塗布し、その後その水溶液を除去しリンスする方法がとられている。本発明は、温度応答性培養皿を利用したなるべく細胞シートそのものを利用しようとする技術である。従って、温度応答性ポリマー層上の細胞接着性タンパク質の被覆量が極度に多くなっては好ましくない。温度応答性ポリマーの被覆量、並びに細胞接着性タンパク質の被覆量の測定は常法に従えば良く、例えばFT−IR−ATRを用いて細胞付着部を直接測る方法、あらかじめラベル化したポリマーを同様な方法で固定化し細胞付着部に固定化されたラベル化ポリマー量より推測する方法などが挙げられるがいずれの方法を用いても良い。In the present invention, the surface of the stretchable base material is coated with the temperature-responsive polymer whose hydration power changes within a temperature range of 0 to 80 ° C., and the base material surface is stretched and / or shrunk. By changing the affinity, it is intended to change the affinity with biomaterials and to develop various applications. In order to realize this, it is essential that the above-described biomaterial is first attached to the surface of the temperature-responsive substrate of the present invention. The condition of the surface of the base material when the biomaterial adheres may be stretched or shrunk under load on the base material surface, and may not be loaded at all. under load, coverage of the temperature responsive polymer to the substrate surface may be in the range of 0.6~2.5μg / cm 2, preferably of 1.1~2.3μg / cm 2 The range is preferably, more preferably in the range of 1.3 to 2.0 μg / cm 2 , and most preferably in the range of 1.5 to 1.8 μg / cm 2 . When the coating amount is less than 0.6 μg / cm 2 , the biomaterial on the polymer is difficult to peel off even if a stimulus is given, and the working efficiency is remarkably deteriorated. On the other hand, when it is 2.5 μg / cm 2 or more, it is difficult for the biomaterial to adhere to the region, and it is difficult to sufficiently attach the biomaterial. In such a case, if the protein is further coated on the temperature-responsive polymer coating layer, the temperature-responsive polymer coating amount on the substrate surface may be 2.3 μg / cm 2 or more, and the temperature response at that time coverage of sexual polymer may have 9.0μg / cm 2 or less, preferably well 8.0μg / cm 2 or less, expediently 7.0μg / cm 2 or less. When the coating amount of the temperature-responsive polymer is 9.0 μg / cm 2 or more, even if the cell-responsive protein is further coated on the temperature-responsive polymer coating layer, it is difficult to attach the biomaterial. Although the kind of such cell adhesion protein is not limited at all, For example, collagen, laminin, laminin 5, Matrigel etc. are individual, or 2 or more types of mixtures are mentioned. In addition, these cell adhesive protein coating methods may be in accordance with conventional methods. Usually, an aqueous solution of biomaterial adhesive protein is applied to the substrate surface, and then the aqueous solution is removed and rinsed. . The present invention is a technique for using a cell sheet itself as much as possible using a temperature-responsive culture dish. Therefore, it is not preferable that the coating amount of the cell adhesive protein on the temperature-responsive polymer layer becomes extremely large. Measurement of the coating amount of the temperature-responsive polymer and the coating amount of the cell adhesive protein may be in accordance with a conventional method. For example, the method of directly measuring the cell attachment part using FT-IR-ATR, the same as the polymer labeled in advance. For example, a method of inferring from the amount of labeled polymer immobilized by a method and immobilized on the cell attachment portion may be used, and any method may be used.
同様に、その生体材料が付着する際の基材表面の温度応答性ポリマー層の厚さについては、その基材表面に負荷が掛かって延伸、もしくは収縮されていても良く、何ら負荷が掛かっていなくても良く、いずれにせよそのいずれかの負荷状態で、基材表面への温度応答性ポリマー層の厚さが、0.1〜100nmの範囲であることが良く、好ましくは1〜50nmの範囲であることが良く、さらに好ましくは5〜25nmの範囲であることが良く、最も好ましくは8〜15nmの範囲であることが良い。0.1nmより少ない厚さのとき、刺激を与えても当該ポリマー上の生体材料は剥離し難く、作業効率が著しく悪くなり好ましくない。逆に100nm以上であると、その領域に生体材料が付着し難く、生体材料を十分に付着させることが困難となる。このような場合、温度応答性ポリマー被覆層の上にさらにタンパク質を被覆すれば、基材表面の温度応答性ポリマー被覆量は2.3μg/cm2以上であっても良く、その際の温度応答性ポリマーの被覆量は9.0μg/cm2以下が良く、好ましくは8.0μg/cm2以下が良く、7.0μg/cm2以下が好都合である。温度応答性ポリマーの被覆量が9.0μg/cm2以上であると温度応答性ポリマー被覆層の上にさらに細胞接着性タンパク質を被覆しても生体材料が付着し難くなり好ましくない。そのような細胞接着性タンパク質の種類は何ら限定されるものではないが、例えば、コラーゲン、ラミニン、ラミニン5、マトリゲル等の単独、もしくは2種以上の混合物が挙げられる。また、これらの細胞接着性タンパク質の被覆方法は常法に従えば良く、通常、生体材料接着性タンパク質の水溶液を基材表面に塗布し、その後その水溶液を除去しリンスする方法がとられている。Similarly, regarding the thickness of the temperature-responsive polymer layer on the base material surface when the biomaterial adheres, the base material surface may be stretched or contracted under load, and any load is applied. In any case, the thickness of the temperature-responsive polymer layer on the substrate surface may be in the range of 0.1 to 100 nm, preferably 1 to 50 nm. The film thickness may be in the range, more preferably in the range of 5 to 25 nm, and most preferably in the range of 8 to 15 nm. When the thickness is less than 0.1 nm, the biomaterial on the polymer is difficult to peel off even if a stimulus is applied, and the working efficiency is remarkably deteriorated. Conversely, when it is 100 nm or more, it is difficult for the biomaterial to adhere to the region, and it is difficult to sufficiently attach the biomaterial. In such a case, if the protein is further coated on the temperature-responsive polymer coating layer, the temperature-responsive polymer coating amount on the substrate surface may be 2.3 μg / cm 2 or more, and the temperature response at that time coverage of sexual polymer may have 9.0μg / cm 2 or less, preferably well 8.0μg / cm 2 or less, expediently 7.0μg / cm 2 or less. When the coating amount of the temperature-responsive polymer is 9.0 μg / cm 2 or more, even if the cell-responsive protein is further coated on the temperature-responsive polymer coating layer, it is difficult to attach the biomaterial. Although the kind of such cell adhesion protein is not limited at all, For example, collagen, laminin, laminin 5, Matrigel etc. are individual, or 2 or more types of mixtures are mentioned. In addition, these cell adhesive protein coating methods may be in accordance with conventional methods. Usually, an aqueous solution of biomaterial adhesive protein is applied to the substrate surface, and then the aqueous solution is removed and rinsed. .
さらに、本発明ではその生体材料が付着する際の基材表面の温度応答性ポリマー層の密度については、その基材表面に負荷が掛かって延伸、もしくは収縮されていても良く、何ら負荷が掛かっていなくても良く、いずれにせよそのいずれかの負荷状態で、基材表面への温度応答性ポリマー層の密度が、0.5〜2.5g/cm3の範囲であることが良く、好ましくは0.7〜2.3g/cm3の範囲であることが良く、さらに好ましくは0.9〜2.0g/cm3の範囲であることが良く、最も好ましくは1.0〜1.6g/cm3の範囲であることが良い。0.5g/cm3より少ない厚さのとき、刺激を与えても当該ポリマー上の生体材料は剥離し難く、作業効率が著しく悪くなり好ましくない。逆に2.5g/cm3より高いと、その領域に生体材料が付着し難く、生体材料を十分に付着させることが困難となる。このような場合、温度応答性ポリマー被覆層の上にさらにタンパク質を被覆すれば、基材表面の温度応答性ポリマー被覆量は2.3μg/cm2以上であっても良く、その際の温度応答性ポリマーの被覆量は9.0μg/cm2以下が良く、好ましくは8.0μg/cm2以下が良く、7.0μg/cm2以下が好都合である。温度応答性ポリマーの被覆量が9.0μg/cm2以上であると温度応答性ポリマー被覆層の上にさらに細胞接着性タンパク質を被覆しても生体材料が付着し難くなり好ましくない。そのような細胞接着性タンパク質の種類は何ら限定されるものではないが、例えば、コラーゲン、ラミニン、ラミニン5、マトリゲル等の単独、もしくは2種以上の混合物が挙げられる。また、これらの細胞接着性タンパク質の被覆方法は常法に従えば良く、通常、生体材料接着性タンパク質の水溶液を基材表面に塗布し、その後その水溶液を除去しリンスする方法がとられている。Furthermore, in the present invention, the density of the temperature-responsive polymer layer on the surface of the base material when the biomaterial adheres may be stretched or contracted by applying a load to the surface of the base material. The density of the temperature-responsive polymer layer on the surface of the base material is preferably in the range of 0.5 to 2.5 g / cm 3 under any load condition. well that may be in the range of 0.7~2.3g / cm 3, still more preferably from 0.9~2.0g / cm 3, and most preferably 1.0~1.6g / Cm 3 is preferable. When the thickness is less than 0.5 g / cm 3 , the biomaterial on the polymer is difficult to peel off even when a stimulus is applied, and the working efficiency is remarkably deteriorated. Conversely, if it is higher than 2.5 g / cm 3, it is difficult for the biomaterial to adhere to the region, and it is difficult to sufficiently attach the biomaterial. In such a case, if the protein is further coated on the temperature-responsive polymer coating layer, the temperature-responsive polymer coating amount on the substrate surface may be 2.3 μg / cm 2 or more, and the temperature response at that time coverage of sexual polymer may have 9.0μg / cm 2 or less, preferably well 8.0μg / cm 2 or less, expediently 7.0μg / cm 2 or less. When the coating amount of the temperature-responsive polymer is 9.0 μg / cm 2 or more, even if the cell-responsive protein is further coated on the temperature-responsive polymer coating layer, it is difficult to attach the biomaterial. Although the kind of such cell adhesion protein is not limited at all, For example, collagen, laminin, laminin 5, Matrigel etc. are individual, or 2 or more types of mixtures are mentioned. In addition, these cell adhesive protein coating methods may be in accordance with conventional methods. Usually, an aqueous solution of biomaterial adhesive protein is applied to the substrate surface, and then the aqueous solution is removed and rinsed. .
本発明における温度応答性ポリマーの構造は架橋ゲル構造あるいは直鎖状構造であり、直鎖状構造の場合、温度応答性ポリマーの分子量は4000〜150000が良く、好ましくは10000〜100000、さらに好ましくは20000〜80000が良い。分子量が4000以下であると温度を変えても細胞を剥離させるだけに十分な親水性の表面とならず本発明の基材表面として好ましいものではなく、逆に分子量が150000以上のポリマー鎖が基材表面に固定化されているとどの温度域においても細胞は付着することができず、本発明の温度応答性基材として好ましくない。 The structure of the temperature-responsive polymer in the present invention is a crosslinked gel structure or a linear structure. In the case of the linear structure, the molecular weight of the temperature-responsive polymer is preferably 4,000 to 150,000, preferably 10,000 to 100,000, and more preferably. 20000 to 80000 is good. If the molecular weight is 4000 or less, even if the temperature is changed, the surface is not hydrophilic enough to detach cells and is not preferred as the substrate surface of the present invention. Conversely, a polymer chain having a molecular weight of 150,000 or more is a group. When immobilized on the surface of the material, cells cannot adhere in any temperature range, which is not preferable as the temperature-responsive substrate of the present invention.
本発明の基材表面は、温度応答性領域,細胞非付着性領域があっても良く、その2層の形態は、上部から観察して、例えば、▲1▼ラインとスペースからなるパターン、▲2▼水玉模様のパターン、▲3▼格子状のパターン、その他特殊な形のパターン、或いはこれらが混ざっている状態のパターンが挙げられ何ら限定されるものではないが、心筋組織、神経等の細胞が配向した各組織の状態を考え、▲1▼ラインとスペースからなるものが好ましい。温度応答性領域,細胞非付着性領域の2層のそれぞれの大きさは何ら限定されるものではないが、得られた細胞シートを剥離した際、収縮することを考え、ライン状のパターンの基材を使用する場合、細胞が付着する温度応答性領域は500nm以下、好ましくは300nm以下、さらに200nm以下、最も好ましくは100nm以下が良い。細胞が付着する温度応答性領域の幅が500nmより大きいとそのライン上で培養した細胞が配向せず好ましくない。その際、本発明における細胞と親和性の低い細胞非付着性高分子とは、細胞が付着しないものならば何ら制約されるものではないが、例えば、ポリ−N−アクリロイルモルホリン、ポリアクリルアミド、ポリジメチルアクリルアミド、ポリエチレングリコール、セルロース等の親水性高分子、或いはシリコーン高分子、フッ素高分子等の強疎水性高分子等が挙げられる。 The substrate surface of the present invention may have a temperature-responsive region and a cell non-adhesive region, and the two-layer form is, for example, (1) a pattern consisting of lines and spaces, (2) Polka dot pattern, (3) Lattice pattern, other specially shaped patterns, or mixed patterns, but not limited, cells such as myocardial tissue and nerves Considering the state of each of the oriented structures, those consisting of (1) lines and spaces are preferred. The size of each of the two layers of the temperature responsive region and the non-cell-adherent region is not limited at all, but it is considered that the obtained cell sheet contracts when the cell sheet is peeled off, and the basis of the line pattern When using a material, the temperature-responsive region to which the cells adhere is 500 nm or less, preferably 300 nm or less, more preferably 200 nm or less, and most preferably 100 nm or less. If the width of the temperature-responsive region to which the cells adhere is larger than 500 nm, the cells cultured on the line are not oriented, which is not preferable. In this case, the cell non-adhesive polymer having a low affinity for cells in the present invention is not limited at all as long as cells do not adhere to it. For example, poly-N-acryloylmorpholine, polyacrylamide, polyacrylamide, Examples thereof include hydrophilic polymers such as dimethylacrylamide, polyethylene glycol, and cellulose, and strongly hydrophobic polymers such as silicone polymers and fluorine polymers.
本発明はこうして準備された生体材料が付着した表面に対し、物理的に伸縮させること、或いは基材周囲の温度を変えること、もしくはこれらを併用することで基材表面に固定化されている温度応答性ポリマー層の状態を変えることで、生体物質を剥離させることができるようになる。その際は、生体物質が付着した状態が、負荷が掛かって延伸、もしくは収縮された状態であっても、何ら負荷が掛かっていなくても、その状態から伸縮、あるいは延伸され、上述した生体材料が付着しない温度応答性ポリマーの被覆量の範囲、温度応答性ポリマーの厚さの範囲、温度応答性ポリマーの密度の範囲となれば良く、その収縮、あるいは延伸する方法等のその他の条件は何ら限定されるものでない。本発明では、伸縮性基材表面に被覆されているポリマーは温度応答性を有しており、基材表面を伸縮させなくとも基材の環境温度を変えることでも生体材料を剥離させることができる。その際、生体材料を温度応答性基材から剥離回収するには、生体材料が付着した培養基材の温度を培養基材上の被覆ポリマーの上限臨界溶解温度以上若しくは下限臨界溶解温度以下にすることによって剥離させることができる。その際、培養液中において行うことも、その他の等張液中において行うことも可能であり、目的に合わせて選択することができる。生体材料をより早く、より高効率に剥離、回収する目的で、基材を軽くたたいたり、ゆらしたりする方法、更にはピペットを用いて培地を撹拌する方法等を単独で、あるいは併用して用いてもよい。 The present invention is the temperature fixed on the surface of the base material by physically expanding or contracting the surface to which the biomaterial prepared in this way is attached, or changing the temperature around the base material, or using them together. By changing the state of the responsive polymer layer, the biological material can be peeled off. In that case, even if the state in which the biological substance is attached is a state in which the load is applied and stretched or contracted, even if no load is applied, the state is expanded or contracted or extended from the state. The range of the temperature-responsive polymer coating amount, the thickness range of the temperature-responsive polymer, and the density range of the temperature-responsive polymer should be within the range. It is not limited. In the present invention, the polymer coated on the surface of the stretchable substrate has temperature responsiveness, and the biomaterial can be peeled by changing the environmental temperature of the substrate without stretching the substrate surface. . At that time, in order to peel and collect the biomaterial from the temperature-responsive substrate, the temperature of the culture substrate to which the biomaterial is attached is set to the upper limit critical solution temperature or lower limit solution temperature of the coating polymer on the culture substrate. Can be peeled off. In that case, it can be performed in a culture solution or in another isotonic solution, and can be selected according to the purpose. For the purpose of exfoliating and recovering biomaterials faster and more efficiently, the method of tapping or shaking the base material, and the method of stirring the culture medium using a pipette alone or in combination It may be used.
本発明を幾つか例を挙げ具体的に示すと以下のようになる。温度応答性高分子を10μg/cm2の値となるように基材に修飾した表面は細胞接着性を示し、この基材をある方向に150%伸展させた場合、高分子の固定化密度は6.7μg/cm2に減少し、より細胞接着性が強い表面となる。同様に12μg/cm2の値で温度応答性高分子で修飾された表面は非細胞接着性を示すが、ある方向に150%伸展させた場合、高分子の固定化密度は8μg/cm2に減少し、細胞接着性を示すようになる。或いは、温度応答性高分子を10μg/cm2の値となるように基材に修飾した表面は細胞接着性を示し、この基材をもとの形状から80%の値になるように収縮させた場合、高分子の固定化密度は12.5μg/cm2に増加し細胞は非接着性を示す。同様に8μg/cm2の値で温度応答性高分子で修飾された表面は非細胞接着性を示すが、ある方向に80%収縮させた場合、高分子の固定化密度は10μg/cm2に増加し、より弱い細胞接着性を示すようになる。さらに、150%伸展させた状態で6.7μg/cm2の温度応答性高分子の固定化密度を示す温度応答性高分子基材表面で細胞を37℃で培養し、コンフルエント後、もとの形状から80%になるまで収縮させた場合、高分子固定化密度は12.5μg/cm2となり細胞をシート状で回収することができる。その際、温度を温度応答性高分子の相転移温度以下にすることで、より高速な剥離ができるようになる。本発明はこれらのことに特に限定されるものではない。Specific examples of the present invention are as follows. The surface of the substrate modified with a temperature-responsive polymer having a value of 10 μg / cm 2 exhibits cell adhesion, and when this substrate is stretched 150% in a certain direction, the immobilization density of the polymer is The surface is reduced to 6.7 μg / cm 2 , resulting in a surface with stronger cell adhesion. Similarly, a surface modified with a temperature-responsive polymer at a value of 12 μg / cm 2 exhibits non-cell adhesion, but when 150% stretched in a certain direction, the immobilization density of the polymer is 8 μg / cm 2 . Decrease and become cell adhesive. Alternatively, the surface of the base material modified with a temperature-responsive polymer having a value of 10 μg / cm 2 exhibits cell adhesion, and the base material is shrunk to a value of 80% from the original shape. In this case, the immobilization density of the polymer is increased to 12.5 μg / cm 2 and the cells are non-adhesive. Similarly, a surface modified with a temperature-responsive polymer at a value of 8 μg / cm 2 exhibits non-cell adhesion, but when the surface is contracted 80% in a certain direction, the immobilization density of the polymer is 10 μg / cm 2 . Increase and show weaker cell adhesion. Furthermore, the cells were cultured at 37 ° C. on the surface of the temperature-responsive polymer substrate showing the immobilization density of the temperature-responsive polymer of 6.7 μg / cm 2 in a state of 150% extension, and after confluence, When contracted to 80% from the shape, the polymer immobilization density is 12.5 μg / cm 2 , and the cells can be collected in sheet form. At that time, by setting the temperature to be equal to or lower than the phase transition temperature of the temperature-responsive polymer, it becomes possible to perform higher speed peeling. The present invention is not particularly limited to these.
このようにして得られた温度応答性基材は、本発明においてさまざまな方法で利用できる。その1例を挙げると、温度応答性基材を非伸縮下、もしくは伸縮させることで特定の状態とし、当該状態に固定した基材表面を利用して生体材料を分離させる、温度応答性基材の利用方法を提供する。本発明では得られた温度応答性基材を特定の伸縮条件、温度条件とすることでさまざまな表面を構築させられ、すなわち1種類の温度応答性基材からさまざまな状態の基材表面が得られることとなる。 The temperature-responsive substrate thus obtained can be used in various ways in the present invention. For example, a temperature-responsive base material is made non-stretched or stretched to a specific state by separating the biomaterial using the base material surface fixed in the state. Provide usage of. In the present invention, various surfaces can be constructed by setting the obtained temperature-responsive substrate to a specific stretching condition and temperature condition, that is, a substrate surface in various states can be obtained from one type of temperature-responsive substrate. Will be.
本発明では、また、特定の状態に固定した基材表面に付着した生体材料を、当該表面の伸縮度を変えず、温度変化することだけでも基材表面に被覆された温度応答性ポリマー層の性質の変化を利用することができる。すなわち、本発明の基材表面に付着した生体材料は基材表面の伸縮度を変えずとも、温度を変えるだけで剥離させることができる。 In the present invention, the temperature-responsive polymer layer coated on the substrate surface can also be obtained by simply changing the temperature of the biomaterial attached to the substrate surface fixed in a specific state without changing the elasticity of the surface. Changes in properties can be used. That is, the biomaterial attached to the substrate surface of the present invention can be peeled off only by changing the temperature without changing the degree of expansion / contraction of the substrate surface.
或いは、本発明では、特定の状態に固定した基材表面に付着した生体材料を、温度を変えず、当該基材表面を収縮することで剥離させることもできる。すなわち、本発明の基材表面に付着した生体材料は基材表面の温度を変えずとも、伸縮度を変えるだけで剥離させることができる。 Or in this invention, the biomaterial adhering to the base-material surface fixed to the specific state can also be made to peel by shrink | contracting the said base-material surface, without changing temperature. That is, the biomaterial attached to the surface of the substrate of the present invention can be peeled only by changing the degree of stretching without changing the temperature of the surface of the substrate.
さらに、本発明では、特定の状態に固定した基材表面に付着した生体材料に対し、温度を変えず、当該表面を伸長することだけでも剥離させられる。このことは温度応答性ポリマー層に付着していた生体材料が、基材表面の延伸により引き離された結果と考えられる。 Furthermore, in this invention, it is made to peel only by extending | stretching the said surface, without changing temperature with respect to the biomaterial adhering to the base-material surface fixed to the specific state. This is considered to be a result of the biomaterial adhering to the temperature-responsive polymer layer being pulled away by stretching the substrate surface.
そして、本発明では、特定の状態に固定した基材表面に付着した生体材料を、当該表面の伸縮度を変え、かつ温度変化することで基材表面に被覆された温度応答性ポリマー層の性質の変化を利用することで剥離させることもできる。本発明の場合、伸縮度を変えることと温度を変えることと併用することでより効率良く生体材料の付着、剥離を制御できるようになる。 In the present invention, the property of the temperature-responsive polymer layer coated on the surface of the biomaterial attached to the surface of the base material fixed in a specific state by changing the degree of expansion and contraction of the surface and changing the temperature. It can also be peeled off by utilizing the change of. In the case of the present invention, it is possible to control the attachment and separation of the biomaterial more efficiently by using in combination with changing the degree of stretching and changing the temperature.
本発明により、これまで、温度応答性細胞培養表面基材の精密な重合条件の設計が必要であったが、ポリマー薄膜の厚みとポリマー固定化密度を同時に制御することで、目的とする培養細胞の性質にあわあせ、温度応答性細胞培養基材を伸展、収縮させることで表面の物性を変化させ、目的細胞の細胞接着および剥離を自由に制御することができる。 According to the present invention, until now, it was necessary to design precise polymerization conditions for the temperature-responsive cell culture surface base material. By controlling the thickness of the polymer thin film and the polymer immobilization density at the same time, Therefore, the surface physical properties can be changed by extending and contracting the temperature-responsive cell culture substrate, and cell adhesion and detachment of the target cells can be freely controlled.
以下に、本発明を実施例に基づいて更に詳しく説明するが、これらは本発明を何ら限定するものではない。 Hereinafter, the present invention will be described in more detail based on examples, but these do not limit the present invention in any way.
市販のシリコンシートを2cm角に切断したものを20枚、酸素条件下でプラズマ処理を行い、70℃の超純水400mLが入ったセパラブルフラスコ内にシリコンシート角を攪拌しながら20枚、添加し、その後に(3−アミノプロピル)トリエトキシシラン 4mLを添加し、30分間反応させた。得られたサンプルをX線光電子分光法(XPS)により表面分析を行い、アミノ基の導入を確認した(図1)。 20 sheets of commercially available silicon sheets cut into 2 cm squares, plasma treated under oxygen conditions, 20 sheets added while stirring the silicon sheet corners in a separable flask containing 400 mL of ultrapure water at 70 ° C Then, 4 mL of (3-aminopropyl) triethoxysilane was added and allowed to react for 30 minutes. The obtained sample was subjected to surface analysis by X-ray photoelectron spectroscopy (XPS) to confirm the introduction of amino groups (FIG. 1).
実施例1で得られた、アミノ化シリコン膜に2−プロパノール溶媒中にN−イロプロピルアクリルアミドを10wt%、30wt%、50wt%、55wt%で溶解させた溶液を作製し、各16μLをアミノ化シリコンシート上に塗布し、その後に電子線照射重合を行い、得られたサンプルを4℃で一晩、浸漬した後、十分な洗浄、乾燥を行い、ポリ(N−イソプロピルアクリルアミド)(PIPAAm)を固定化したシリコンシート得た(10wt%、30wt%、50wt%の条件で作製したサンプルは10IP−Silicon、30IP−Silicon、50IP−Silicon、55IP−Siliconと標記)。各条件で作製したPIPAAm固定化シリコンシートのFT−IR/ATRスペクトルとXPSの表面元素組成分析値を図2、図3に示す。FT−IR/ATRのスペクトルが示すように、1650cm−1付近のPIPAAmのカルボニル基の吸収ピークが仕込みモノマー濃度の増加とともに増加していることから、仕込みモノマー濃度によりPIPAAm固定化量が増大していることを確認した。XPSの表面分析結果からも、仕込みモノマー濃度の増加により窒素原子組成の増加を示したことから、PIPAAmの仕込みモノマー依存性が確認された。A solution obtained by dissolving N-Iropropylacrylamide at 10 wt%, 30 wt%, 50 wt%, and 55 wt% in 2-propanol solvent was prepared on the aminated silicon film obtained in Example 1, and 16 μL of each was aminated. After coating on a silicon sheet, followed by electron beam irradiation polymerization, the obtained sample was immersed overnight at 4 ° C., and then sufficiently washed and dried to obtain poly (N-isopropylacrylamide) (PIPAAm). A fixed silicon sheet was obtained (samples prepared under conditions of 10 wt%, 30 wt%, and 50 wt% were labeled as 10 IP-Silicon, 30 IP-Silicon, 50 IP-Silicon, and 55 IP-Silicon). The FT-IR / ATR spectrum and the XPS surface element composition analysis values of the PIPAAm-immobilized silicon sheet prepared under each condition are shown in FIGS. As the spectrum of FT-IR / ATR shows, the absorption peak of the carbonyl group of PIPAAm near 1650 cm −1 increases with the charged monomer concentration, so that the amount of PIPAAm immobilized increases with the charged monomer concentration. I confirmed. The XPS surface analysis results also showed an increase in nitrogen atom composition due to an increase in the charged monomer concentration, confirming the dependence of PIPAAm on the charged monomer.
実施例2で作製したPPIAAm固定化シリコンシートの温度変化による表面濡れ性の変化を静的接触角測定法により評価した(図4)。原料となるシリコンシート(Silicon)は高い接触角を示し、温度による大きな接触角変化は示さなかった。また、シリコンシートへのアミノ基導入(NH2−Silicon)より、接触角は減少したが、温度変化による大きな接触角変化は示さなかった。PIPAAm固定化量が少ない10IP−Silicon、30IP−Siliconでは、シリコンシートよりも、さらに低い接触角を示したが、温度変化による大きな接触角変化は見られなかった。50IP−Siliconでは温度変化による接触角の変化を示した。これらの結果から、親水性、疎水性変化が顕著に起こるためには一定量のPIPAAmがシリコンシート表面に固定化される必要があることが確認できた。The change in surface wettability due to temperature change of the PPIAAm-immobilized silicon sheet produced in Example 2 was evaluated by a static contact angle measurement method (FIG. 4). The silicon sheet (Silicon) as a raw material showed a high contact angle and did not show a large change in contact angle due to temperature. In addition, the contact angle decreased due to the introduction of amino groups into the silicon sheet (NH 2 -Silicon), but a large contact angle change due to temperature change was not shown. 10IP-Silicon and 30IP-Silicon with a small amount of PIPAAm immobilization showed a lower contact angle than the silicon sheet, but a large contact angle change due to temperature change was not observed. 50IP-Silicon showed changes in contact angle due to temperature changes. From these results, it was confirmed that a certain amount of PIPAAm needs to be immobilized on the surface of the silicon sheet in order to cause a significant change in hydrophilicity and hydrophobicity.
実施例2で作製した50IP−Siliconを用い非伸縮状態とx−y軸方向に1.13倍伸展した状態で細胞培養および細胞剥離を行った(図5、図6)。コントロールとして、実施例1で作製したアミノ基を導入したシリコンシート(NH2−Silicon)を利用した。37℃で細胞播種してから24時間後の細胞接着性はNH2−Siliconを100とした場合、非伸展および伸展させたPIPAAm−Silicon表面への細胞接着性は大きな違いは確認できなかった。一方、温度を20℃に変化させた場合、NH2−Siliconからは非伸展、伸展にかかわらず、20%程度の剥離挙動が確認できた。50IP−Siliconの非伸展からは効果的な細胞剥離が観察された。しかし、伸展させた50IP−Siliconからは、非伸展と比較して、効果的な細胞剥離が確認できなかった。この結果は50IP−Siliconの伸展により、固定化したPIPAAm層の密度、厚みが減少し、より疎水性表面となり接着細胞が剥離しにくくなったためである。Cell culture and cell detachment were performed using the 50IP-Silicon produced in Example 2 in a non-stretched state and 1.13 times extended in the xy axis direction (FIGS. 5 and 6). As a control, the silicon sheet (NH 2 -Silicon) introduced with the amino group prepared in Example 1 was used. The cell adhesiveness 24 hours after cell seeding at 37 ° C., when NH 2 -Silicon was set to 100, could not confirm a large difference in the cell adhesiveness to the non-extended and extended PIPAAm-Silicon surface. On the other hand, when the temperature was changed to 20 ° C., a peeling behavior of about 20% could be confirmed from NH 2 -Silicon regardless of non-extension or extension. Effective cell detachment was observed from non-extension of 50IP-Silicon. However, from the extended 50IP-Silicon, effective cell detachment could not be confirmed as compared with non-extended. This result is because the density and thickness of the immobilized PIPAAm layer are reduced by the extension of 50IP-Silicon, and the surface becomes more hydrophobic and adherent cells are difficult to peel off.
実施例4で使用した50IP−Siliconの細胞培養後に低温処理、トリプシン処理により細胞および表面への接着タンパク質を除去した後の走査型電子顕微鏡像を図7に示す。伸展培養後の表面にはクラックなどの亀裂が入っていないことが確認できた。この結果は、伸展した50IP−Silicon表面から細胞がはがれにくい原因はシリコンシート層の亀裂によって引き起こされるものではなく、固定化したPIPAAm層の見かけの密度、厚みの違いによって引き起こされることを示している。 FIG. 7 shows a scanning electron microscope image after removing cells and surface adhesion proteins by low-temperature treatment and trypsin treatment after cell culture of 50IP-Silicon used in Example 4. It was confirmed that the surface after the extension culture had no cracks such as cracks. This result indicates that the reason why the cells are difficult to peel off from the extended 50IP-Silicon surface is not caused by the crack of the silicon sheet layer, but is caused by the difference in the apparent density and thickness of the immobilized PIPAAm layer. .
60wt% IPAAmモノマー濃度で作製した表面を用いて、7.8 x 103 cells/cm2の播種密度でウシ血管内皮細胞を播種し、37℃で7日間、培養を行った後に、20℃のインキュベーターに本基材を移動した所、30分間から70分の間にシート状として回収することを確認した(図8)。Bovine vascular endothelial cells were seeded at a seeding density of 7.8 × 10 3 cells / cm 2 using a surface prepared at a concentration of 60 wt% IPAAm monomer, and cultured at 37 ° C. for 7 days. When this base material was moved to the incubator, it was confirmed that it was recovered as a sheet in 30 minutes to 70 minutes (FIG. 8).
ポリ−N−イソプロピルアクリルアミドが基材表面に2.0μg/cm2(もとの形状から150%伸展後、強い細胞接着性)被覆された表面で線維芽細胞を37℃でコンフルエントになるまで培養させた。培養後、このものを収縮させ、ポリ−N−イソプロピルアクリルアミドが基材表面に3.7μg/cm2(もとの形状から80%収縮、非細胞接着性)の状態にすることで、37℃で細胞をシート状で回収できた。Fibroblasts are cultured at 37 ° C. until they become confluent at a surface coated with 2.0 μg / cm 2 of poly-N-isopropylacrylamide on the surface of the substrate (strength cell adhesion after 150% extension from the original shape). I let you. After culturing, this was contracted, and the poly-N-isopropylacrylamide was brought to a state of 3.7 μg / cm 2 (80% contraction from the original shape, non-cell adhesiveness) on the surface of the substrate. The cells could be recovered in sheet form.
ポリ−N−イソプロピルアクリルアミドが基材表面に2.0μg/cm2(もとの形状から150%伸展後、強い細胞接着性)被覆された表面で線維芽細胞を37℃でコンフルエントになるまで培養させた。培養後、このものを収縮させ、ポリ−N−イソプロピルアクリルアミドが基材表面に3.7μg/cm2(もとの形状から80%収縮、非細胞接着性)とし、さらにポリマーの相転移温度以下にすることで、150%伸展状態の表面よりも高速に細胞をシート状で回収できた。Fibroblasts are cultured at 37 ° C. until they become confluent at a surface coated with 2.0 μg / cm 2 of poly-N-isopropylacrylamide on the surface of the substrate (strength cell adhesion after 150% extension from the original shape). I let you. After culturing, this was shrunk so that poly-N-isopropylacrylamide was 3.7 μg / cm 2 (80% shrunk from the original shape, non-cell-adhesiveness) on the substrate surface, and further below the phase transition temperature of the polymer As a result, the cells could be recovered in a sheet form at a higher speed than the 150% stretched surface.
本発明であれば、温度応答性ポリマーを被覆した1種類の基材を準備すれば、その基材を伸縮することで生体材料の親和性を変えられ、多様な用途への展開をはかれる世界に類のない新規な発想による極めて重要な発明と考えている。 In the present invention, if one kind of base material coated with a temperature-responsive polymer is prepared, the affinity of biomaterials can be changed by expanding and contracting the base material, and it can be developed for various uses. We consider it an extremely important invention based on an unprecedented new idea.
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JP2008263863A (en) * | 2007-04-20 | 2008-11-06 | Dainippon Printing Co Ltd | Cell culture support and method for producing the same |
JP2010017128A (en) * | 2008-07-10 | 2010-01-28 | Toyota Central R&D Labs Inc | Cultured cell-handling article, production method thereof and use thereof |
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JP2003038170A (en) * | 2001-07-26 | 2003-02-12 | Mitsuo Okano | Anterior eye part-associated cell sheet, three- dimensional structure and method for producing them |
JP2008263863A (en) * | 2007-04-20 | 2008-11-06 | Dainippon Printing Co Ltd | Cell culture support and method for producing the same |
JP2010017128A (en) * | 2008-07-10 | 2010-01-28 | Toyota Central R&D Labs Inc | Cultured cell-handling article, production method thereof and use thereof |
WO2010044417A1 (en) * | 2008-10-14 | 2010-04-22 | 株式会社セルシード | Temperature-responsive cell culture substrate and method for producing same |
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JP2014209853A (en) * | 2013-04-17 | 2014-11-13 | 大日本印刷株式会社 | Method for producing substrate for cell culture |
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