Novel Platform for Regulation of Extracellular Vesicles and Metabolites Secretion from Cells Using a Multi-Linkable Horizontal Co-Culture Plate

Novel Platform for Regulation of Extracellular Vesicles and Metabolites Secretion from Cells Using a Multi-Linkable Horizontal Co-Culture Plate

Microfluidics is applied in biotechnology research via the creation of microfluidic channels and reaction vessels. Filters are considered to be able to simulate microfluidics. A typical example is the cell culture insert, which comprises two vessels connected by a filter. Cell culture inserts have b...

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Detalles Bibliográficos
Autores principales: Takeo Shimasaki, Satoko Yamamoto, Risa Omura, Kagenori Ito, Yumiko Nishide, Hideki Yamada, Kazumi Ohtomo, Tomo Ishisaka, Keiichiro Okano, Takenori Ogawa, Hiroyuki Tsuji, Yoichi Matsuo, Toshinari Minamoto, Naohisa Tomosugi, Etienne Ferain, Takahiro Ochiya
Formato: article
Lenguaje:EN
Publicado: MDPI AG 2021
Materias:
co-culture plate
multiple connection
horizontal co-culture
extracellular vesicles
exosome
track-etched-membrane
Mechanical engineering and machinery
TJ1-1570
Acceso en línea:https://doaj.org/article/3db5e14965d9480aa9c15f4763df7c82
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Sumario:Microfluidics is applied in biotechnology research via the creation of microfluidic channels and reaction vessels. Filters are considered to be able to simulate microfluidics. A typical example is the cell culture insert, which comprises two vessels connected by a filter. Cell culture inserts have been used for years to study cell-to-cell communication. These systems generally have a bucket-in-bucket structure and are hereafter referred to as a vertical-type co-culture plate (VTCP). However, VTCPs have several disadvantages, such as the inability to simultaneously observe samples in both containers and the inability of cell-to-cell communication through the filters at high cell densities. In this study, we developed a novel horizontal-type co-culture plate (HTCP) to overcome these disadvantages and confirm its performance. In addition, we clarified the migration characteristics of substances secreted from cells in horizontal co-culture vessels. It is generally assumed that less material is exchanged between the horizontal vessels. However, the extracellular vesicle (EV) transfer was found to be twice as high when using HTCP. Other merits include control of the degree of co-culture via the placement of cells. We believe that this novel HTCP container will facilitate research on cell-to-cell communication in various fields.

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