Atsuko Takamatsu
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Explore the profile of Atsuko Takamatsu including associated specialties, affiliations and a list of published articles.
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14
Citations
176
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Recent Articles
1.
Yoneoka E, Takamatsu A
Front Cell Dev Biol
. 2023 Nov;
11:1249165.
PMID: 38020888
The question of whether a single-celled organism without a brain could have functions such as learning and memory has been the subject of much debate in recent years. The plasmodium...
2.
Yamamoto H, Fukasawa Y, Shoji Y, Hisamoto S, Kikuchi T, Takamatsu A, et al.
BMC Microbiol
. 2021 Aug;
21(1):227.
PMID: 34399691
Background: Bacteria have been reported to exhibit complicated morphological colony patterns on solid media, depending on intracellular, and extracellular factors such as motility, cell propagation, and cell-cell interaction. We isolated...
3.
Okumura K, Nishikawa S, Omori T, Ishikawa T, Takamatsu A
Phys Rev E
. 2018 May;
97(3-1):032411.
PMID: 29776148
To gain insight into the nature of biological synchronization at the microscopic scale, we here investigate the hydrodynamic synchronization between conically rotating objects termed nodal cilia. A mechanical model of...
4.
Nishikawa S, Takamatsu A, Ohsawa S, Igaki T
J Theor Biol
. 2016 May;
404:40-50.
PMID: 27234645
The phenomenon of 'cell competition' has been implicated in the normal development and maintenance of organs, such as in the regulation of organ size and suppression of neoplastic development. In...
5.
Takamatsu A, Shinohara K, Ishikawa T, Hamada H
Phys Rev Lett
. 2014 Aug;
110(24):248107.
PMID: 25165968
Rotational movement of mouse node cilia generates leftward fluid flow in the node cavity, playing an important role in left-right determination in the embryo. Although rotation of numerous cilia was...
6.
Transportation network with fluctuating input/output designed by the bio-inspired Physarum algorithm
Watanabe S, Takamatsu A
PLoS One
. 2014 Mar;
9(2):e89231.
PMID: 24586616
In this paper, we propose designing transportation network topology and traffic distribution under fluctuating conditions using a bio-inspired algorithm. The algorithm is inspired by the adaptive behavior observed in an...
7.
Takamatsu A, Ishikawa T, Shinohara K, Hamada H
Phys Rev E Stat Nonlin Soft Matter Phys
. 2013 Jun;
87(5):050701.
PMID: 23767475
Rotational movement of isolated single cilia in mice embryo was investigated, which generates leftward fluid flow in the node cavity and plays an important role in left-right determination. The leftward...
8.
Nakamura T, Saito D, Kawasumi A, Shinohara K, Asai Y, Takaoka K, et al.
Nat Commun
. 2012 Dec;
3:1322.
PMID: 23271656
Breaking of left-right symmetry in mouse embryos requires fluid flow at the node, but the precise action of the flow has remained unknown. Here we show that the left-right asymmetry...
9.
Shinohara K, Kawasumi A, Takamatsu A, Yoshiba S, Botilde Y, Motoyama N, et al.
Nat Commun
. 2012 Jan;
3:622.
PMID: 22233632
Determination of left-right asymmetry in mouse embryos is achieved by a leftward fluid flow (nodal flow) in the node cavity that is generated by clockwise rotational movement of 200-300 cilia...
10.
Watanabe S, Tero A, Takamatsu A, Nakagaki T
Biosystems
. 2011 May;
105(3):225-32.
PMID: 21620930
Traffic optimization of railroad networks was considered using an algorithm that was biologically inspired by an amoeba-like organism, plasmodium of the true slime mold, Physarum polycephalum. The organism developed a...