研究者業績

坪田 健一

ツボタ ケンイチ  (Ken-ichi Tsubota)

基本情報

所属
千葉大学 大学院工学研究院 教授
学位
修士(工学)(神戸大学)
博士(工学)(神戸大学)

J-GLOBAL ID
200901047004111715
researchmap会員ID
5000041810

外部リンク

論文

 92
  • Ken-ichi Tsubota, Shota Horikoshi, Tetsuya Hiraiwa, Satoru Okuda
    2024年11月3日  
    Abstract Living tissues exhibit complex mechanical properties, including viscoelastic and elastoplastic responses, that are crucial for regulating cell behaviors and tissue deformations. Despite their significance, the intricate properties of three-dimensional (3D) multicellular tissues are not well understood and are inadequately implemented in biomaterial engineering. To address this gap, we developed a numerical method to analyze the dynamic properties of multicellular tissues using a 3D vertex model framework. By focusing on 3D tissues composed of confluent homogeneous cells, we characterized their properties in response to various deformation magnitudes and time scales. Stress relaxation tests revealed that large deformations initially induced relaxation in the shapes of individual cells. This process is amplified by subsequent transient cell rearrangements, homogenizing cell shapes and leading to tissue fluidization. Additionally, dynamic viscoelastic analyses showed that tissues exhibited strain softening and hysteresis during large deformations. Interestingly, this strain softening originates from multicellular structures independent of cell rearrangement, while hysteresis arises from cell rearrangement. Moreover, tissues exhibit elastoplastic responses over the long term, which are well represented by the Ramberg–Osgood model. These findings highlight the characteristic properties of multicellular tissues emerging from their structures and rearrangements, especially during long-term large deformations. The developed method offers a new approach to uncover the dynamic nature of 3D tissue mechanics and could serve as a technical foundation for exploring tissue mechanics and advancing biomaterial engineering.
  • Wei Deng, Ken-ichi Tsubota
    Medical Engineering & Physics 104 103809-103809 2022年6月  査読有り
  • XinYue Liu, Keni-chi Tsubota, Yi Yu, Wang Xi, XiaoBo Gong
    Science China Physics, Mechanics & Astronomy 65(6) 264612 2022年6月  査読有り
  • Wei Deng, Ken-ichi Tsubota
    Processes 10(5) 1005-1005 2022年5月18日  査読有り
    A numerical simulation was carried out to investigate the blood flow behavior (i.e., flow rate and pressure) and coupling of a renal vascular network and the myogenic response to various conditions. A vascular segment and an entire kidney vascular network were modeled by assuming one single vessel as a straight pipe whose diameter was determined by Murray’s law. The myogenic response was tested on individual AA (afferent artery)–GC (glomerular capillaries)–EA (efferent artery) systems, thereby regulating blood flow throughout the vascular network. Blood flow in the vascular structure was calculated by network analysis based on Hagen–Poiseuille’s law to various boundary conditions. Simulation results demonstrated that, in the vascular segment, the inlet pressure Pinlet and the vascular structure act together on the myogenic response of each individual AA–GC–EA subsystem, such that the early-branching subsystems in the vascular network reached the well-regulated state first, with an interval of the inlet as Pinlet = 10.5–21.0 kPa, whereas the one that branched last exhibited a later interval with Pinlet = 13.0–24.0 kPa. In the entire vascular network, in contrast to the Pinlet interval (13.0–20.0 kPa) of the unified well-regulated state for all AA–GC–EA subsystems of the symmetric model, the asymmetric model exhibited the differences among subsystems with Pinlet ranging from 12.0–17.0 to 16.0–20.0 kPa, eventually achieving a well-regulated state of 13.0–18.5 kPa for the entire kidney. Furthermore, when Pinlet continued to rise (e.g., 21.0 kPa) beyond the vasoconstriction range of the myogenic response, high glomerular pressure was also related to vascular structure, where PGC of early-branching subsystems was 9.0 kPa and of late-branching one was 7.5 kPa. These findings demonstrate how the myogenic response regulates renal blood flow in vascular network system that comprises a large number of vessel elements.
  • Ken-ichi Tsubota, Kazuki Namioka
    Journal of Biomechanics 137 111081-111081 2022年5月  査読有り筆頭著者責任著者

MISC

 237
  • 坪田健一
    HPCIシステム利用研究課題 利用報告書 2024年2月  筆頭著者責任著者
  • 坪田健一
    HPCIシステム利用研究課題 利用報告書 2023年9月  筆頭著者責任著者
  • 平原 良樹, 山本 創太, 坪田 健一
    バイオエンジニアリング講演会講演論文集 2016(28) "2C23-1"-"2C23-5" 2016年1月9日  
    In car accidents abdominal organ injuries are frequently caused by seat belts which induce compression to the abdomen. Therefore much attention has been paid to reducing the injuries caused by the protection device. Accordingly there is a need for injury assessment tool abdominal organs. The purpose of this study is developing the injury analysis model that can be expressed liver damage state by the MPS (Moving Particle Semi-implicit) method. At first to represents the viscoelastic behavior of liver tissue, we modified the Navier-Stokes equations by adopting Voigt elements between every neighboring particles. Next we set the material properties of the liver by simulating tensile test and compression test using the simplified geometric model. Finally we conducted a simulation of the impact test of the liver. As a result the liver model represents a qualitatively the mechanical properties. However the Liver model has different maximum stress, it is not possible to quantitatively express the mechanical properties.
  • 大日方 宏幸, 坪田 健一
    バイオエンジニアリング講演会講演論文集 2016(28) "2E34-1"-"2E34-4" 2016年1月9日  
    Considering high-shear-induced platelet activation, we carried out a computer simulation of thrombus formation in a stenosed flow channel using a particle method. A model blood consisted of plasma and platelets, and platelet aggregation was represented by connecting platelet particles by springs. As a result of simulation, platelet particles were activated by high shear at a stenosis, and they adhered to channel wall surfaces in the rear of the stenosis. Shapes of platelet aggregates and its growth speed depended on thresholds of shear rate and exposure time to determine flow-dependent platelet activation. Platelet aggregation area at the lower channel wall whose shape changed along a main flow direction decreased with an increasing threshold of exposure time. The platelet aggregation area at the upper channel wall whose shape was straight along a main flow direction decreased with an increasing threshold of high shear rate. The platelet aggregation shapes corresponded with a previously published in vitro experimental result when a threshold shear rate was greater than 17,000 s^<-1> which is smaller than experimentally estimated value of 30,000 s^<-1> or greater. Platelet aggregation area increased faster than that observed in an in vitro experiment because a large number of platelet were assumed in simulations.
  • 遠藤 豊, 杉本 晃一, 劉 浩, 坪田 健一
    バイオエンジニアリング講演会講演論文集 2016(28) "1E15-1"-"1E15-4" 2016年1月9日  
    We performed a computer simulation for effects of an anticoagulant agent on thrombus formation under the influence of the blood flow, assuming a rat arteriovenous shunt in which a nylon filament was inserted. A blood model consisted of a normal blood and a thrombus, and they were expressed by an assembly of particles. A normal blood particle close to the nylon filament was changed to a thrombus particle when the shear rate was lower than a threshold value. An anticoagulant effect depending on a drug concentration inhibited changes from normal blood particles to thrombus ones. As a result of computer simulation, thrombus was formed with a thickness from 0.1 mm to 0.4 mm around the nylon filament. Thrombus weight decreased with an increasing dose, which was qualitatively consistent with an experimental result, while, thrombus weight in the simulation was approximately 15-20% of that in the experiment. It is necessary to improve the simulation model toward quantitative identification of an experimentally observed anticoagulant effect.

講演・口頭発表等

 9

共同研究・競争的資金等の研究課題

 19