研究者業績

山田 真澄

ヤマダ マスミ  (Masumi Yamada)

基本情報

所属
千葉大学 大学院工学研究院 共生応用化学コース 教授
学位
博士(工学)(2006年3月 東京大学)

J-GLOBAL ID
200901066152886720
researchmap会員ID
6000014797

論文

 90
  • Ayumi Hayashi, Runa Hemmi, Yuhei Saito, Rie Utoh, Tatsuo Taniguchi, Masumi Yamada
    Analytical Chemistry 96(17) 6764-6773 2024年4月30日  査読有り最終著者責任著者
    Tremendous efforts have been made to develop practical and efficient microfluidic cell and particle sorting systems; however, there are technological limitations in terms of system complexity and low operability. Here, we propose a sheath flow generator that can dramatically simplify operational procedures and enhance the usability of microfluidic cell sorters. The device utilizes an embedded polydimethylsiloxane (PDMS) sponge with interconnected micropores, which is in direct contact with microchannels and seamlessly integrated into the microfluidic platform. The high-density micropores on the sponge surface facilitated fluid drainage, and the drained fluid was used as the sheath flow for downstream cell sorting processes. To fabricate the integrated device, a new process for sponge-embedded substrates was developed through the accumulation, incorporation, and dissolution of PMMA microparticles as sacrificial porogens. The effects of the microchannel geometry and flow velocity on the sheath flow generation were investigated. Furthermore, an asymmetric lattice-shaped microchannel network for cell/particle sorting was connected to the sheath flow generator in series, and the sorting performances of model particles, blood cells, and spiked tumor cells were investigated. The sheath flow generation technique developed in this study is expected to streamline conventional microfluidic cell-sorting systems as it dramatically improves versatility and operability.
  • Shota Mashiyama, Runa Hemmi, Takeru Sato, Atsuya Kato, Tatsuo Taniguchi, Masumi Yamada
    Lab on a Chip 24(2) 171-181 2024年1月17日  査読有り最終著者責任著者
    Although droplet microfluidics has been studied for the past two decades, its applications are still limited due to the low productivity of microdroplets resulting from the low integration of planar microchannel structures. In this study, a microfluidic system implementing inverse colloidal crystals (ICCs), a spongious matrix with regularly and densely formed three-dimensional (3D) interconnected micropores, was developed to significantly increase the throughput of microdroplet generation. A new bottom-up microfabrication technique was developed to seamlessly integrate the ICCs into planar microchannels by accumulating non-crosslinked spherical PMMA microparticles as sacrificial porogens in a selective area of a mold and later dissolving them. We have demonstrated that the densely arranged micropores on the spongious ICC of the microchannel function as massively parallel micronozzles, enabling droplet formation on the order of >10 kHz. Droplet size could be adjusted by flow conditions, fluid properties, and micropore size, and biopolymer particles composed of polysaccharides and proteins were produced. By further parallelization of the unit structures, droplet formation on the order of >100 kHz was achieved. The presented approach is an upgrade of the existing droplet microfluidics concept, not only in terms of its high throughput, but also in terms of ease of fabrication and operation.
  • Yuken Hasebe, Masumi Yamada, Rie Utoh, Minoru Seki
    Journal of Bioscience and Bioengineering 135(5) 417-422 2023年5月  責任著者
    Technologies for efficiently expanding Chinese hamster ovary (CHO) cells, the primary host cells for antibody production, are of growing industrial importance. Various processes for the use of microcarriers in CHO suspension cultures have been developed, but there have been very few studies on cell-adhesive microcarriers that are similar in size to cells. In this study, we proposed a new approach to suspension cultures of CHO cells using cell-sized condensed and crosslinked gelatin microparticles (GMPs) as carriers. Unlike commercially available carriers with sizes typically greater than 100 μm, each cell can adhere to the surface of multiple particles and form loose clusters with voids. We prepared GMPs of different average diameters (27 and 48 μm) and investigated their effects on cell adhesion and cluster formation. In particular, small GMPs promoted cell proliferation and increased IgG4 production by the antibody-producing CHO cell line. The data obtained in this study suggest that cell-sized particles, rather than larger ones, enhance cell proliferation and function, providing useful insights for improving suspension-culture-based cell expansion and cell-based biologics production for a wide range of applications.
  • Mai Takagi, Masumi Yamada, Rie Utoh, Minoru Seki
    Lab on a Chip 23(9) 2257-2267 2023年5月  責任著者
    Spheroid formation assisted by microengineered chambers is a versatile approach for morphology-controlled three-dimensional (3D) cell cultivation with physiological relevance to human tissues. However, the limitation in diffusion-based oxygen/nutrient transport has been a critical issue for the densely packed cells in spheroids, preventing maximization of cellular functions and thus limiting their biomedical applications. Here, we have developed a multiscale microfluidic system for the perfusion culture of spheroids, in which porous microchambers, connected with microfluidic channels, were engineered. A newly developed process of centrifugation-assisted replica molding and salt-leaching enabled the formation of single micrometer-sized pores on the chamber surface and in the substrate. The porous configuration generates a vertical flow to directly supply the medium to the spheroids, while avoiding the formation of stagnant flow regions. We created seamlessly integrated, all PDMS/silicone-based microfluidic devices with an array of microchambers. Spheroids of human liver cells (HepG2 cells) were formed and cultured under vertical-flow perfusion, and the proliferation ability and liver cell-specific functions were compared with those of cells cultured in non-porous chambers with a horizontal flow. The presented system realizes both size-controlled formation of spheroids and direct medium supply, making it suitable as a precision cell culture platform for drug development, disease modelling, and regenerative medicine.
  • Natsumi Shimmyo, Makoto Furuhata, Masumi Yamada, Rie Utoh, Minoru Seki
    Analyst 147(8) 1622-1630 2022年4月  責任著者
    Numerous attempts have been made to develop efficient systems to purify trace amounts of circulating tumor cells (CTCs) from blood samples. However, current technologies are limited by complexities in device fabrication, system design, and process operability. Here we describe a facile, scalable, and highly efficient approach to physically capturing CTCs using a rationally designed microfluidic isolator with an array of microslit channels. The wide but thin microslit channels with a depth of several micrometers selectively capture CTCs, which are larger and less deformable than other blood cells, while allowing other blood cells to just flow through. We investigated in detail the effects of the microchannel geometry and operating parameters on the capture efficiency and selectivity of several types of cultured tumor cells spiked in blood samples as the CTC model. Additionally, in situ post-capture staining of the captured cells was demonstrated to investigate the system's applicability to clinical cancer diagnosis. The presented approach is simple in operation but significantly effective in capturing specific cells and hence it may have great potential in implementating cell physics-based CTC isolation techniques for cancer liquid biopsy.

MISC

 159
  • 山田真澄
    化学とマイクロ・ナノシステム学会誌 19(2) 42-43 2020年9月  筆頭著者最終著者責任著者
  • 山田真澄
    ぶんせき 341-341 2020年9月  筆頭著者責任著者
  • Hideki Iwadate, Naoki Kimura, Rina Hashimoto, Yuya Yajima, Rie Utoh, Masumi Yamada, Minoru Seki
    21st International Conference on Miniaturized Systems for Chemistry and Life Sciences, MicroTAS 2017 177-178 2020年  
    A new process is presented to fabricate basement membrane-mimetic cell co-culture platforms using microfabricated PDMS stencil plates. An aqueous solution of extracellular matrices (ECM) was introduced into the through-holes of the microstencil plate and then dried, to form vitrified and condensed ECM films. Because the microstencil plate physically supported the films, we were able to produce significantly thin ECM films with a thickness of 0.5-2 μm, which is comparable to the basement membranes in vivo (< 1 μm). We co-cultured heterotypic cells on both sides of the film, demonstrating the usability of the presented platform in investigating cellular physiology.
  • Mayu Fukushi, Yuya Yajima, Rie Utoh, Masumi Yamada, Kazuya Furusawa, Minoru Seki
    21st International Conference on Miniaturized Systems for Chemistry and Life Sciences, MicroTAS 2017 1145-1146 2020年  
    Here we present a new approach to rapid formation of collagen gel tubes using microfluidic devices made of phosphate particle-embedding PDMS (PP-PDMS). An acidic solution of collagen, introduced into the PP-PDMS channel, was rapidly transformed into a hydrogel layer on the channel surface because it was neutralized by the phosphate ions supplied from the PP-PDMS substrate. After removing the non-gelled collagen solution at the center, collagen gel tubes were obtained. Based on this concept, we successfully fabricated vascular tissue-like multilayered structures incorporating vascular endothelial cells (ECs) and smooth muscle cells (SMCs). The presented technique is highly useful for preparing functional tubular tissues that reconstituted the in vivo tissue-like extracellular matrix environments.
  • Natsumi Shimmyo, Makoto Furuhata, Masumi Yamada, Rie Utoh, Minoru Seki
    MicroTAS 2020 - 24th International Conference on Miniaturized Systems for Chemistry and Life Sciences 1155-1156 2020年  
    Here we present an efficient microfluidic system for selectively capturing circulating tumor cells (CTCs) from blood samples, employing parallelized structures of cell trappers. The thin configuration of the trapper (depth of several micrometers) enables capture of CTCs based on physical characteristics; CTCs are larger and less-deformable than other blood cells. Parallelization of the cell trappers achieved high-throughput processing of the blood sample (~100 µL/min) and a high capture efficiency (~90%) of CTCs despite the simple configuration of the trapper. The presented system would be applicable to easy, low-cost, and highly sensitive cancer diagnosis for tumor patients.

書籍等出版物

 5

共同研究・競争的資金等の研究課題

 22

産業財産権

 22