{"id":4958,"date":"2025-10-20T16:42:45","date_gmt":"2025-10-20T07:42:45","guid":{"rendered":"https:\/\/jteccorp.wdkb.jp\/?page_id=4958"},"modified":"2026-03-19T16:04:47","modified_gmt":"2026-03-19T07:04:47","slug":"cellpet-3d-ips","status":"publish","type":"page","link":"https:\/\/www.j-tec.co.jp\/english\/life-science\/cellpet-3d-ips\/","title":{"rendered":"CellPet 3D-iPS"},"content":{"rendered":"\n<div class=\"phead\">\n<div class=\"c-life-title cellpet-3d-ips en \">\n                <h1>\n                  <span class=\"logo\"><img src=\"\/assets\/img\/lifescience\/logo_cellfloat_w.svg\" alt=\"CellFloat\"><\/span>\n                  <span class=\"txt1\">3D Rotational Floating Culture Device<br>\nCellPet 3D-iPS<\/span><span class=\"txt2\"><img src=\"\/assets\/img\/lifescience\/cellpet-3d-ips\/logo.webp\" alt=\"CellPet 3D-iPS\"><\/span>\n                <\/h1>\n                <p class=\"text-box\">Effortless Spheroid Formation for iPS\/ES Cells<br>\nSupporting Highly Reproducible Cultures<\/p>\n              <\/div>\n    <div class=\"c-localnavi\">\n      <ul class=\"localnavi-list\">\n        <li class=\"localnavi-item\">\n          <a href=\"#feature\">Product Features<\/a>\n        <\/li>\n        <li class=\"localnavi-item\">\n          <a href=\"#paper\">Related papers<\/a>\n        <\/li>\n        <li class=\"localnavi-item\">\n          <a href=\"#technology\">3D Rotational<br class=\"sp\"> Floating Culture<\/a>\n        <\/li>\n        <li class=\"localnavi-item\">\n          <a href=\"#application\">Application Notes<\/a>\n        <\/li>\n        <li class=\"localnavi-item\">\n          <a href=\"#spec\">Product<br class=\"sp\"> Specifications<\/a>\n        <\/li>\n      <\/ul>\n    <\/div>\n  <\/div>\n  <p class=\"u-text-right u-mt10 u-fs14\">\u203bImage after culture and immunostaining<\/p>\n  <div class=\"l-detail-content__inner\">\n    <p class=\"c-lead u-mb60\"> Proprietary 3D rotational floating culture technology applicable to spheroid formation and differentiation induction <\/p>\n    <!-- Product Features Section -->\n    <section class=\"c-section\">\n      <a id=\"feature\" class=\"u-scroll-point\"><\/a>\n      <h2 class=\"c-title l2\">Product Features<\/h2>\n      <div class=\"c-col2 -half\">\n        <div class=\"c-col2__item\">\n          <div class=\"c-image u-text-center\">\n            <div style=\"max-width: 500px;margin: 0 auto\"><img src=\"\/assets\/img\/lifescience\/cellpet-3d-ips\/cellpet3dips.webp\" alt=\"CellPet 3D-iPS\"><\/div>\n          <\/div>\n        <\/div>\n        <div class=\"c-col2__item\">\n          <div class=\"c-text\">\n            <ul class=\"c-list u-fs16\">\n              <li style=\"margin-right:-1em\">Realizes a culture environment with gentle flow generated by slow rotation<\/li>\n              <li>Obtain spheroids with uniform particle size and easily perform 3D culture<\/li>\n              <li>Reduces contamination risk with externally sealed culture vessel<\/li>\n              <li>Disposable culture vessel using gas-permeable resin<\/li>\n            <\/ul>\n          <\/div>\n          <div class=\"c-text u-mt30\">\n            <h3 class=\"c-title l3 u-mb20\">Examples of culture results<\/h3>\n            <ul class=\"c-list\">\n              <li>iPS cells<\/li>\n              <li>ES cells<\/li>\n              <li>Differentiated cells derived from iPS cells<\/li>\n              <li>Human-derived cancer cells<\/li>\n            <\/ul>\n          <\/div>\n          <div class=\"u-mt30\">\n            <h3 class=\"u-fs20 u-mb20  u-color-black\">Growth images of iPS cell spheroids<\/h3>\n            <div class=\"c-image 2 \"><img src=\"\/assets\/img\/lifescience\/cellpet-3d-ips\/img_product5-2-en.webp\" alt=\"CellPet 3D-iPS\"><\/div>\n          <\/div>\n        <\/div>\n      <\/div>\n      <div class=\"c-fix-button__buttons -inpage\">\n        <a href=\"\/english\/contact\/\" class=\"c-fix-button__btn -contact\">\n          <span>Contact<\/span>\n          \n            \n          \n        <\/a>\n      <\/div>\n      <a id=\"paper\" class=\"u-scroll-point\"><\/a>\n      <div class=\"c-text u-mt60\">\n        <h3 class=\"c-title l2\">Related papers<\/h3>\n        <div class=\"\">\n          <p style=\"margin-bottom: 10px\"> J. Takahashi et al., \u201cControlled aggregative assembly to form self-organizing macroscopic human intestine from induced pluripotent stem cells\u201d, <em>Cell Rep. Methods<\/em>, vol. 4, no. 12, p. 100930, Dec. 2024.<br><a href=\"http:\/\/doi.org\/10.1016\/j.crmeth.2024.100930\" class=\"c-icon -blank\" target=\"_blank\" rel=\"noopener\">http:\/\/doi.org\/10.1016\/j.crmeth.2024.100930<\/a>\n          <\/p>\n          <p style=\"margin-bottom: 10px\">J. Takahashi et al., \u201cProtocol to generate large human intestinal organoids using a rotating bioreactor\u201d, <em>STAR Protoc.<\/em>, vol. 4, no. 3, p. 102374, Sep. 2023.<br><a href=\"https:\/\/doi.org\/10.1016\/j.xpro.2023.102374\" target=\"_blank\" class=\"c-icon -blank\" rel=\"noopener\">https:\/\/doi.org\/10.1016\/j.xpro.2023.102374<\/a>\n          <\/p>\n          <p> J. Takahashi et al., \u201cSuspension culture in a rotating bioreactor for efficient generation of human intestinal organoids\u201d, <em>Cell Rep. Methods<\/em>, vol. 2, no. 11, p. 100337, Nov. 2022.<br><a href=\"http:\/\/doi.org\/10.1016\/j.crmeth.2022.100337\" target=\"_blank\" class=\"c-icon -blank\" rel=\"noopener\">http:\/\/doi.org\/10.1016\/j.crmeth.2022.100337<\/a>\n          <\/p>\n        <\/div>\n      <\/div>\n    <\/section>\n  \n    <!-- 3D Rotational Floating Culture Technology Section -->\n    <section class=\"c-section\">\n      <a id=\"technology\" class=\"u-scroll-point\"><\/a>\n      <h2 class=\"c-title l2\">Our Proprietary Technology \u201d3D Rotational Floating Culture Technology &#8220;CELLFLOAT&#8221;<\/h2>\n      <div class=\"c-col2 -half -ac\">\n        <div class=\"c-col2__item\">\n          <div class=\"c-image u-text-center\">\n            <img class=\"u-w70-sp\" src=\"\/assets\/img\/lifescience\/cellpet-3d-ips\/CELLFLAT_img-en.webp\" alt=\"3D Rotational Floating Culture Technology CELLFLOAT\">\n          <\/div>\n        <\/div>\n        <div class=\"c-col2__item\">\n          <div class=\"c-text\">\n            <div class=\"c-image\">\n              <img class=\"cellfloat\" src=\"\/assets\/img\/lifescience\/cellpet-3d-ips\/CELLFLOAT_RED-1.webp\" alt=\"CELLFLOAT\">\n            <\/div>\n            <h3 class=\"c-title l3 u-mt20\">What is CELLFLOAT?<\/h3>\n            <p class=\"u-mt20\"> CELLFLOAT is our proprietary 3D rotational floating culture technology.<br>This is a method of culturing cells (spheroids) in a floating state (non-adhesive) by balancing the buoyancy and gravitational force that the cells (spheroids) receive from the flow generated by constantly rotating the cylindrical culture vessel. Stable culture results can be expected due to moderate shear stress from the constant gentle flow, removal of waste products produced by the cells themselves such as lactic acid, and proper nutrient absorption from the culture medium.<\/p>\n          <\/div>\n        <\/div>\n      <\/div>\n    <\/section>\n    <!-- Application Notes Section -->\n    <section class=\"c-section\">\n      <a id=\"application\" class=\"u-scroll-point\"><\/a>\n      <h2 class=\"c-title l2\">Application Notes<\/h2>  <div class=\"c-applinote\">  <div class=\"c-applinote__item\">\r\n        <h3 class=\"c-applinote__title\">Analysis of Exosome Secretion from Human Mesenchymal Stromal Cell Spheroids<\/h3>\r\n        <div class=\"flex\">\r\n            <div class=\"c-applinote__image\">  <img src=\"https:\/\/www.j-tec.co.jp\/english\/wp-content\/uploads\/sites\/3\/2025\/12\/Analysis-of-Exosome-Secretion-from-Human-Mesenchymal-Stromal-Cell-Spheroids-300x225-2.jpg\" alt=\"Analysis of Exosome Secretion from Human Mesenchymal Stromal Cell Spheroids\">   <a href=\"https:\/\/www.j-tec.co.jp\/english\/wp-content\/uploads\/sites\/3\/2025\/06\/Analysis-of-Exosome-Secretion-from-Human-Mesenchymal-Stromal-Cell-Spheroids.pdf\" class=\"c-button -pdf\" target=\"_blank\" rel=\"noopener\">PDF<\/a>  <\/div>\r\n            <div class=\"c-applinote__content\">\r\n                <div class=\"c-applinote__text\"><!-- wp:paragraph -->\n<p>We generated adipose-derived human mesenchymal stromal cell spheroids (hMSC-AdpS) with uniform particle size using CellPet 3D-iPS. After enzymatic dissociation of the hMSC-AdpS and subsequent static culture in exosome production medium, exosome yield was approximately 1.3 times higher compared to the control.<\/p>\n<!-- \/wp:paragraph --><\/div>\r\n            <\/div>\r\n        <\/div>\r\n    <\/div>  <div class=\"c-applinote__item\">\r\n        <h3 class=\"c-applinote__title\">Chondrogenic differentiation from hMSC spheroids<\/h3>\r\n        <div class=\"flex\">\r\n            <div class=\"c-applinote__image\">  <img src=\"https:\/\/www.j-tec.co.jp\/english\/wp-content\/uploads\/sites\/3\/2025\/12\/Induction-of-chondrogenic-differentiation-of-human-mesenchymal-stem-cell-spheroids_EN-2-300x225-1.jpg\" alt=\"Chondrogenic differentiation from hMSC spheroids\">   <a href=\"https:\/\/www.j-tec.co.jp\/english\/wp-content\/uploads\/sites\/3\/2024\/06\/Induction-of-chondrogenic-differentiation-of-human-mesenchymal-stem-cell-spheroids_EN.pdf\" class=\"c-button -pdf\" target=\"_blank\" rel=\"noopener\">PDF<\/a>  <\/div>\r\n            <div class=\"c-applinote__content\">\r\n                <div class=\"c-applinote__text\"><!-- wp:paragraph -->\n<p>We generated spheroids of human mesenchymal stromal cells using CellPet 3D-iPS and induced chondrogenic differentiation by switching the culture medium. Compared to chondrogenic differentiation in monolayer culture, the spheroids produced greater amounts of hyaluronic acid and elastic fibers. Additionally, cartilage lumen, a characteristic feature of mature cartilage tissue, were observed within the tissue.<\/p>\n<!-- \/wp:paragraph --><\/div>\r\n            <\/div>\r\n        <\/div>\r\n    <\/div>  <div class=\"c-applinote__item\">\r\n        <h3 class=\"c-applinote__title\">Gas permeability evaluation of disposable culture vessels<\/h3>\r\n        <div class=\"flex\">\r\n            <div class=\"c-applinote__image\">  <img src=\"https:\/\/www.j-tec.co.jp\/english\/wp-content\/uploads\/sites\/3\/2025\/12\/cac6a32f975648b0373bf8b173bf3ad7-300x225-2.png\" alt=\"Gas permeability evaluation of disposable culture vessels\">   <a href=\"https:\/\/www.j-tec.co.jp\/english\/wp-content\/uploads\/sites\/3\/2024\/05\/Gas-Permeability-Evaluation-of-Disposable-Culture-Vessels.pdf\" class=\"c-button -pdf\" target=\"_blank\" rel=\"noopener\">PDF<\/a>  <\/div>\r\n            <div class=\"c-applinote__content\">\r\n                <div class=\"c-applinote__text\"><!-- wp:paragraph -->\n<p>We evaluated the gas permeability of the disposable vessel of CellPet 3D-iPS. After removing oxygen and carbon dioxide from the culture medium by nitrogen bubbling, the extent to which each gas permeated the vessel and dissolved into the culture medium was examined. After about one hour, the concentration of dissolved oxygen in the vessels reached the same level as that in the culture dish.<\/p>\n<!-- \/wp:paragraph --><\/div>\r\n            <\/div>\r\n        <\/div>\r\n    <\/div>  <div class=\"c-applinote__item\">\r\n        <h3 class=\"c-applinote__title\">hMSC spheroid culture using CellPet 3D-iPS<\/h3>\r\n        <div class=\"flex\">\r\n            <div class=\"c-applinote__image\">  <img src=\"https:\/\/www.j-tec.co.jp\/english\/wp-content\/uploads\/sites\/3\/2025\/12\/Spheroid-culture-of-human-mesenchymal-stem-cells-using-CellPet-3D-iPS-1-300x225-1.jpg\" alt=\"hMSC spheroid culture using CellPet 3D-iPS\">   <a href=\"https:\/\/www.j-tec.co.jp\/english\/wp-content\/uploads\/sites\/3\/2024\/05\/Spheroid-culture-of-human-mesenchymal-stem-cells-using-CellPet-3D-iPS.pdf\" class=\"c-button -pdf\" target=\"_blank\" rel=\"noopener\">PDF<\/a>  <\/div>\r\n            <div class=\"c-applinote__content\">\r\n                <div class=\"c-applinote__text\"><!-- wp:paragraph -->\n<p>We performed spheroid culture of human mesenchymal stromal cells using CellPet 3D-iPS. The cells were seeded into a culture vessel, and the medium was replaced every three days. On day six, the spheroids were enzymatically dissociated into single cells, and the cells were divided into two equal parts, which were then seeded into two separate culture vessels to continue the culture. Over the 12-day culture period, we observed an approximately eight-fold increase in cell proliferation. The diameter distribution of the obtained spheroids was uniform, and it was confirmed that the characteristics of mesenchymal stromal cells were maintained.<\/p>\n<!-- \/wp:paragraph --><\/div>\r\n            <\/div>\r\n        <\/div>\r\n    <\/div>  <div class=\"c-applinote__item\">\r\n        <h3 class=\"c-applinote__title\">iPS spheroid culture using CellPet 3D-iPS<\/h3>\r\n        <div class=\"flex\">\r\n            <div class=\"c-applinote__image\">  <img src=\"https:\/\/www.j-tec.co.jp\/english\/wp-content\/uploads\/sites\/3\/2025\/12\/Feeder-free-culture-of-human-iPS-cells-2-300x225-2.jpg\" alt=\"iPS spheroid culture using CellPet 3D-iPS\">   <a href=\"https:\/\/www.j-tec.co.jp\/english\/wp-content\/uploads\/sites\/3\/2024\/05\/Feeder-free-culture-of-human-iPS-cells.pdf\" class=\"c-button -pdf\" target=\"_blank\" rel=\"noopener\">PDF<\/a>  <\/div>\r\n            <div class=\"c-applinote__content\">\r\n                <div class=\"c-applinote__text\"><!-- wp:paragraph -->\n<p>We performed spheroid culture of iPS cells using CellPet 3D-iPS. Upon evaluating the size distribution of the spheroids on day 4 of culture, approximately 60% had a diameter of 200-300 \u03bcm, indicating the formation of uniform iPS spheroids. It was also confirmed that the expression of undifferentiated markers was maintained during culture with CellPet 3D-iPS.<\/p>\n<!-- \/wp:paragraph --><\/div>\r\n            <\/div>\r\n        <\/div>\r\n    <\/div>  <div class=\"c-applinote__item\">\r\n        <h3 class=\"c-applinote__title\">Gas-permeable ability of disposable culture vessels<\/h3>\r\n        <div class=\"flex\">\r\n            <div class=\"c-applinote__image\">  <img src=\"https:\/\/www.j-tec.co.jp\/english\/wp-content\/uploads\/sites\/3\/2025\/12\/Gas-permeable-ability-of-disposable-culture-vessel-300x225-2.jpg\" alt=\"Gas-permeable ability of disposable culture vessels\">   <a href=\"https:\/\/www.j-tec.co.jp\/english\/wp-content\/uploads\/sites\/3\/2024\/05\/Gas-permeable-ability-of-disposable-culture-vessel.pdf\" class=\"c-button -pdf\" target=\"_blank\" rel=\"noopener\">PDF<\/a>  <\/div>\r\n            <div class=\"c-applinote__content\">\r\n                <div class=\"c-applinote__text\"><!-- wp:paragraph -->\n<p>We performed spheroid cultures of iPS cells and osteosarcoma cells using both a newly developed disposable culture vessel and a conventional glass culture vessel. The disposable vessel, which has excellent gas permeability, was able to maintain a high dissolved oxygen concentration during spheroid culture. Additionally, the use of the disposable vessel enabled the formation of spheroids in osteosarcoma cells, which was not possible with the glass vessel.<\/p>\n<!-- \/wp:paragraph --><\/div>\r\n            <\/div>\r\n        <\/div>\r\n    <\/div>  <div class=\"c-applinote__item\">\r\n        <h3 class=\"c-applinote__title\">iPS trilineage differentiation using CellPet 3D-iPS<\/h3>\r\n        <div class=\"flex\">\r\n            <div class=\"c-applinote__image\">  <img src=\"https:\/\/www.j-tec.co.jp\/english\/wp-content\/uploads\/sites\/3\/2025\/12\/Trilineage-differentiation-derived-human-iPS-cells-2-300x225-2.png\" alt=\"iPS trilineage differentiation using CellPet 3D-iPS\">   <a href=\"https:\/\/www.j-tec.co.jp\/english\/wp-content\/uploads\/sites\/3\/2024\/05\/Trilineage-differentiation-derived-human-iPS-cells.pdf\" class=\"c-button -pdf\" target=\"_blank\" rel=\"noopener\">PDF<\/a>  <\/div>\r\n            <div class=\"c-applinote__content\">\r\n                <div class=\"c-applinote__text\"><!-- wp:paragraph -->\n<p>We performed 3D rotary floating cultures of iPS cells using CellPet 3D-iPS. When using APEL2 medium, an increase in the expression of the trilineage differentiation markers Sox1, PDGFR\u03b1, and Sox17 was observed. This suggests that spheroid cultures using APEL2 medium and CellPet 3D-iPS can induce differentiation.<\/p>\n<!-- \/wp:paragraph --><\/div>\r\n            <\/div>\r\n        <\/div>\r\n    <\/div>  <\/div>\n    <\/section>\n    \n    <div class=\"c-fix-button__buttons -inpage\">\n      <a href=\"\/english\/contact\/\" class=\"c-fix-button__btn -contact\">\n        <span>Contact<\/span>\n        \n          \n        \n      <\/a>\n    <\/div>\n    <!-- Product Specifications Section -->\n    <section class=\"c-section\">\n      <a id=\"spec\" class=\"u-scroll-point\"><\/a>\n      <h2 class=\"c-title l2\">Product Specifications<\/h2>\n      <h4 class=\"c-title l4 u-mt40 u-mb20\">CellPet 3D-iPS<\/h4>\n      <div class=\"c-table blue -scroll\">\n        <table>\n          <tbody>\n            <tr>\n              <th class=\"-w30\">Model<\/th>\n              <td>CELLPET iPS\/3S\/MA-2.1<\/td>\n            <\/tr>\n            <tr>\n              <th>Rotation speed range<\/th>\n              <td>5 \u2013 50 rpm<\/td>\n            <\/tr>\n            <tr>\n              <th>Size<\/th>\n              <td>Width 176 mm \u00d7 Depth 176 mm \u00d7 Hight 100 mm<\/td>\n            <\/tr>\n            <tr>\n              <th>Weight<\/th>\n              <td>3.3 kg<\/td>\n            <\/tr>\n            <tr>\n              <th>Ambient temperature<\/th>\n              <td>15 \u2013 40 degrees Celsius (Usable in CO<sub>2<\/sub> incubator)<\/td>\n            <\/tr>\n            <tr>\n              <th>Ambient humidity<\/th>\n              <td>Relative humidity 30 \u2013 95% (Usable in CO<sub>2<\/sub> incubator)<\/td>\n            <\/tr>\n          <\/tbody>\n        <\/table>\n      <\/div>\n      <h4 class=\"c-title l4 u-mt40 u-mb20\">Controller for CellPet 3D-iPS<\/h4>\n      <div class=\"c-table blue -scroll\">\n        <table>\n          <tbody>\n            <tr>\n              <th class=\"-w30\">Model<\/th>\n              <td>CELLPET iPS\/CO3-2.1<\/td>\n            <\/tr>\n            <tr>\n              <th>Number of CellPet 3D-iPS units connected<\/th>\n              <td>Max. 3 units<\/td>\n            <\/tr>\n            <tr>\n              <th>Display Monitor<\/th>\n              <td>6.5 inch touch panel LCD<\/td>\n            <\/tr>\n            <tr>\n              <th>Size<\/th>\n              <td>Width 200 mm \u00d7 Depth 303 mm \u00d7 Hight 151.8 mm<\/td>\n            <\/tr>\n            <tr>\n              <th>Weight<\/th>\n              <td>4.3 kg (Excluding cables)<\/td>\n            <\/tr>\n            <tr>\n              <th>Input power<\/th>\n              <td>AC 100 V 0.2 A<\/td>\n            <\/tr>\n            <tr>\n              <th>Ambient temperature<\/th>\n              <td>15 \u2013 30 degrees Celsius<\/td>\n            <\/tr>\n            <tr>\n              <th>Ambient humidity<\/th>\n              <td>Relative humidity 30 \u2013 80%<\/td>\n            <\/tr>\n          <\/tbody>\n        <\/table>\n      <\/div>\n      <h4 class=\"c-title l4 u-mt40 u-mb20\">Controller for CellPet 3D-iPS for Academic<\/h4>\n      <div class=\"c-table blue -scroll\">\n        <table>\n          <tbody>\n            <tr>\n              <th class=\"-w30\">Model<\/th>\n              <td>CELLFLOAT\/CO1<\/td>\n            <\/tr>\n            <tr>\n              <th>Number of CellPet 3D-iPS units connected<\/th>\n              <td>Max. 1 unit<\/td>\n            <\/tr>\n            <tr>\n              <th>Size<\/th>\n              <td>Width 98 mm \u00d7 Depth 230 mm \u00d7 Hight 137.5 mm<\/td>\n            <\/tr>\n            <tr>\n              <th>Weight<\/th>\n              <td>1.5 kg<\/td>\n            <\/tr>\n            <tr>\n              <th>Input power<\/th>\n              <td>AC 100\uff5e240 V 0.1 A<\/td>\n            <\/tr>\n            <tr>\n              <th>Ambient temperature<\/th>\n              <td>15 \u2013 30 degrees Celsius<\/td>\n            <\/tr>\n            <tr>\n              <th>Ambient humidity<\/th>\n              <td>Relative humidity 30 \u2013 80%<\/td>\n            <\/tr>\n          <\/tbody>\n        <\/table>\n      <\/div>\n      <p class=\"u-mt40\" style=\"font-weight: 700\">\u25a0CellPet 3D-iPS is for research use only.<\/p>\n      <h3 class=\"c-title l2 u-mt60 u-mb20\">Consumables<\/h3>\n      <div class=\"c-table blue -scroll\">\n        <table>\n          <thead>\n            <tr>\n              <th>Product Name<\/th>\n              <th>Specifications<\/th>\n              <th>Quantity per pack<\/th>\n              <th>Product Code<\/th>\n            <\/tr>\n          <\/thead>\n          <tbody>\n            <tr>\n              <td rowspan=\"3\" class=\"-w30\">Disposable culture vessel<\/td>\n              <td style=\"min-width: 160px\">Volume: 10 mL<\/td>\n              <td>6 vessels<\/td>\n              <td>CELLPET VES\/S10\/6<\/td>\n            <\/tr>\n            <tr>\n              <td>Volume: 30 mL<\/td>\n              <td>6 vessels<\/td>\n              <td>CELLPET VES\/S30\/6<\/td>\n            <\/tr>\n            <tr>\n              <td>Volume: 50 mL<\/td>\n              <td>6 vessels<\/td>\n              <td>CELLPET VES\/S50\/6<\/td>\n            <\/tr>\n          <\/tbody>\n        <\/table>\n      <\/div>\n      <p class=\"u-mt40\" style=\"font-weight: 700\">\u25a0These Consumables are for research use only.<\/p>\n    <\/section>\n  <\/div>\n\n\n\n<div class=\"c-fix-button\">\n    <button class=\"c-fix-button__close\" aria-label=\"Close\">\n      \n        <img loading=\"lazy\" src=\"\/assets\/img\/icon-close02.svg\" alt=\"\" width=\"24\" height=\"24\">\n      \n    <\/button>\n    <div class=\"c-fix-button__inner\">\n      <p class=\"c-fix-button__text\">\n        For product inquiries, click here\n      <\/p>\n      <div class=\"c-fix-button__buttons\">\n        <a href=\"\/english\/contact\/\" class=\"c-fix-button__btn -contact\">\n          <span>Contact<\/span>\n          \n            \n          \n        <\/a>\n      <\/div>\n    <\/div>\n  <\/div>\n","protected":false},"excerpt":{"rendered":"<p>CELLFLOAT utilizes a cylindrical vessel design and is employed from iPS cell spheroid formation through to differentiation induction.<\/p>\n","protected":false},"author":1,"featured_media":7317,"parent":4897,"menu_order":32,"comment_status":"closed","ping_status":"closed","template":"page-life-science-detail.php","meta":[],"acf":[],"aioseo_notices":[],"_links":{"self":[{"href":"https:\/\/www.j-tec.co.jp\/english\/wp-json\/wp\/v2\/pages\/4958"}],"collection":[{"href":"https:\/\/www.j-tec.co.jp\/english\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/www.j-tec.co.jp\/english\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/www.j-tec.co.jp\/english\/wp-json\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"https:\/\/www.j-tec.co.jp\/english\/wp-json\/wp\/v2\/comments?post=4958"}],"version-history":[{"count":9,"href":"https:\/\/www.j-tec.co.jp\/english\/wp-json\/wp\/v2\/pages\/4958\/revisions"}],"predecessor-version":[{"id":7644,"href":"https:\/\/www.j-tec.co.jp\/english\/wp-json\/wp\/v2\/pages\/4958\/revisions\/7644"}],"up":[{"embeddable":true,"href":"https:\/\/www.j-tec.co.jp\/english\/wp-json\/wp\/v2\/pages\/4897"}],"wp:featuredmedia":[{"embeddable":true,"href":"https:\/\/www.j-tec.co.jp\/english\/wp-json\/wp\/v2\/media\/7317"}],"wp:attachment":[{"href":"https:\/\/www.j-tec.co.jp\/english\/wp-json\/wp\/v2\/media?parent=4958"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}