Theoretical Physical Biology Group

Institute of Physics, Academia Sinica, Taiwan (IoP, AS)
- participating in PALM (Physics of Active and Living Matters) labs group
Mechanobiology Institute, National University of Singapore (MBI, NUS)

The names group members are bolded and underlined. * means contact authors. # means equal contribution.

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S. Tanida, K. Fuji, L. Lu, T. Guyomar, B. H. Lee, A. Honigmann, A. Grapin-Botton, D. Riveline, T. Hiraiwa*, M. Nonomura*,Masaki Sano* (2025)
Predicting organoid morphology through a phase field model: Insights into cell division and lumenal pressure.

PLoS Computational Biology 21(8): e1012090. 10.1371/journal.pcbi.1012090

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K. Tsubota*, S. Horikoshi, T. Hiraiwa, S. Okuda* (2025) 

Strain softening and hysteresis arising from 3D multicellular dynamics during long-term large deformation. 

Journal of the Mechanical Behavior of Biomedical Materials 168, 107001. 10.1016/j.jmbbm.2025.107001

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M. Mukenhirn, C.-H. Wang, T. Guyomar, M. J. Bovyn, M. F. Staddon, R. Maraspini, L. Lu, C. Martin-Lemaitre, M. Sano, T. Hiraiwa, D. Riveline*, A. Honigmann* (2024). 

Tight junctions regulate lumen morphology via hydrostatic pressure and junctional tension.

Developmental Cell. 10.1016/j.devcel.2024.07.016

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R. Das*, T. Sakaue, G. V. Shivashankar, J. Prost*, T. Hiraiwa* (2024).

Transient-linking activity enhances subnuclear dynamics by affecting chromatin remodeling.  

Physical Review Letters. 132, 058401. 10.1103/PhysRevLett.132.058401

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S. Okuda*, T. Hiraiwa (2023).

Modelling contractile ring formation and division to daughter cells for simulating proliferative multicellular dynamics. 

The European Physical Journal E. 46, 56. 10.1140/epje/s10189-023-00315-5

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H. Delanoë-Ayari, T. Hiraiwa, P. Marcq, J.-P. Rieu, T. B. Saw (2023). 

2.5D Traction Force Microscopy: Imaging three-dimensional cell forces at interfaces and biological applications.

The International Journal of Biochemistry & Cell Biology. 161, 106432. 10.1016/j.biocel.2023.106432

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S. Okuda*, T. Hiraiwa (2023). 

Long-term adherent cell dynamics emerging from energetic and frictional interactions at the interface. 

Physical Review E. 107, 034406. 10.1103/PhysRevE.107.034406​

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Y. Lou*, J.-F. Rupprecht*, S. Theis, T. Hiraiwa*, T. Saunders* (2023)

Curvature-induced cell rearrangements in biological tissues. 

Physical Review Letters. 130, 108401.  10.1103/PhysRevLett.130.108401

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T. Kawaue, I. Yow, Y. Pan, A.P. Le, Y. Lou, M. Loberas, T. Hiraiwa, ... & Y. Toyama*. (2023).

Inhomogeneous mechanotransduction defines the spatial pattern of apoptosis-induced compensatory proliferation.

Developmental Cell 58(4):267-277.e5. 10.1016/j.devcel.2023.01.005

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R. Das*, T. Sakaue, G. V. Shivashankar, J. Prost, T. Hiraiwa* (2022).

How enzymatic activitiy is involved in chromatin organization:

eLife 11:e79901 [Journal]

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T. Hiraiwa*, R. Akiyama, D. Inoue, A.Md, R. Kabir, A. Kakugo (2022).

Collision-induced torque mediates the transition of chiral dynamic patterns formed by active particles:

Physical Chemistry Chemical Physics 24, 28782-28787 [Journal] [Back cover image (created by Dr. Inoue)]

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S. Okuda*, K. Sato, T. Hiraiwa (2022).

Continuum modeling of non-conservative fluid membrane for simulating long-term cell dynamics: 

The European Physical Journal E. 45, 69 [Journal]

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Y. Lou*, T. Kawaue, I.Yow, Y. Toyama, J. Prost, T. Hiraiwa* (2022).

Interfacial friction and substrate deformation mediate long-range signal propagation in tissues:

Biomechanics and Modeling in Mechanobiology, 21(3):1-20 [Journal] [Official shared PDF]

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K. Fuji, S. Tanida, M. Sano, M.. Nonomura, D. Riveline, H. Honda, T. Hiraiwa* (2022)

Computational approaches for simulating luminogenesis:

Seminars in Cell& Developmental Biology 131: 173-185 [Journal]

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T. Hiraiwa* (2022). 

Dynamic self-organization of migrating cells under constraints by spatial confinement and epithelial integrity: 

The European Physical Journal E (Invited for Topical Collection “Tissue Mechanics”), 45, 16. [Journal]

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F. Afroze, D. Inoue, T. I. Farhana, T. Hiraiwa, R. Akiyama, A. Md. R. Kabir, K. Sada, A. Kakugo* (2021).

Monopolar flocking of microtubules in collective motion: 

Biochemical and Biophysical Research Communications. 563, 23 [Journal].

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T. Hiraiwa* (2020).

Dynamical self-organization of idealized migrating cells by contact communication: 

Physical Review Letters 125, 268104. [Journal]

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T. Yamamoto*, T. Hiraiwa, T. Shibata* (2020).

Collective cell migration of epithelial cells driven by chiral torque generation: 

Physical Review Research 2, 043326 [Journal]

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R. Sakamoto, M. Tanabe, T. Hiraiwa, K. Suzuki, S. Ishiwata, Y. T. Maeda, M. Miyazaki* (2020).

Tug-of-war between actomyosin-driven antagonistic forces determines the positioning symmetry in cell-sized confinement: 

Nature Communications. 11, 3063 [Journal].

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M. Hayakawa, T. Hiraiwa, Y. Wada, H. Kuwayama, T. Shibata* (2020).

Polar pattern formation induced by contact following locomotion in a multicellular system: 

eLife. 9: e53609. [Journal] [eLife digest]