Transport networks are ubiquitous in multicellular organisms and include leaf veins, fungal mycelia and blood vessels. While transport of materials and signals through the network plays a crucial role in maintaining the living system, the transport capacity of the network can best be understood in terms of hydrodynamics. We report here that plasmodium from the large, single-celled amoeboid Physarum was able to construct a hydrodynamically optimized vein-network when evacuating biomass from confined arenas of various shapes through a narrow exit. Increasingly thick veins developed towards the exit, and the network spanned the arena via repetitive bifurcations to give a branching tree. The Hausdorff distance from all parts of the plasmodium t...
A model is presented to explain the development of flow channels within the cytoplasm of the plasmod...
<div><p>In this paper, we propose designing transportation network topology and traffic distribution...
Transport networks are vital components of multicellular organisms, distributing nutrients and remov...
Transport networks are ubiquitous in multicellular organisms and include leaf veins, fungal mycelia ...
The single-celled organism Physarum polycephalum efficiently constructs and minimises dynamical nutr...
Cord-forming fungi form extensive networks that continuously adapt to maintain an efficient transpor...
Understanding how biological systems solve problems could aid the design of novel computational meth...
Cord-forming fungi form extensive networks that continuously adapt to maintain an efficient transpor...
Cord-forming fungi form extensive networks that continuously adapt to maintain an efficient transpor...
We evaluate different ridge-enhancement and segmentation methods to automatically extract the networ...
We describe here a mathematical model of the adaptive dynamics of a transport network of the true sl...
Many biological systems require extensive networks to transport resources and information. Biologica...
Mycelial fungi and acellular slime molds grow as self-organized networks that explore new territory ...
査読付原著論文インパクトファクター(2.21)被引用回数(39)責任著者 Toshiyuki NakagakiWe describe here a mathematical model of the ...
© 2015, Jagellonian University. All rights reserved. The giant unicellular slime mould Physarum poly...
A model is presented to explain the development of flow channels within the cytoplasm of the plasmod...
<div><p>In this paper, we propose designing transportation network topology and traffic distribution...
Transport networks are vital components of multicellular organisms, distributing nutrients and remov...
Transport networks are ubiquitous in multicellular organisms and include leaf veins, fungal mycelia ...
The single-celled organism Physarum polycephalum efficiently constructs and minimises dynamical nutr...
Cord-forming fungi form extensive networks that continuously adapt to maintain an efficient transpor...
Understanding how biological systems solve problems could aid the design of novel computational meth...
Cord-forming fungi form extensive networks that continuously adapt to maintain an efficient transpor...
Cord-forming fungi form extensive networks that continuously adapt to maintain an efficient transpor...
We evaluate different ridge-enhancement and segmentation methods to automatically extract the networ...
We describe here a mathematical model of the adaptive dynamics of a transport network of the true sl...
Many biological systems require extensive networks to transport resources and information. Biologica...
Mycelial fungi and acellular slime molds grow as self-organized networks that explore new territory ...
査読付原著論文インパクトファクター(2.21)被引用回数(39)責任著者 Toshiyuki NakagakiWe describe here a mathematical model of the ...
© 2015, Jagellonian University. All rights reserved. The giant unicellular slime mould Physarum poly...
A model is presented to explain the development of flow channels within the cytoplasm of the plasmod...
<div><p>In this paper, we propose designing transportation network topology and traffic distribution...
Transport networks are vital components of multicellular organisms, distributing nutrients and remov...