Yusuke Ikemoto scite author profile

By adjustments to the concentrations of agarose, GdCl3, and NaCl, the relaxation times and conductivity of almost all types of human tissues can be simulated by CAGN-3.0T phantoms. The phantoms have T1 values of 395-2601 ms, T2 values of 29-334 ms, and conductivity of 0.27-1.26 S/m when concentrations of agarose, GdCl3, and NaCl are varied from 0 to 2.0 w/w%, 0 to 180 μmol/kg, and 0 to 0.7 w/w%, respectively. The CAGN-3.0T phantom has sufficient strength to replicate the torso without using reinforcing agents, and can be cut with a knife into any shape.

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Thermodynamic implications of high <i>Q</i><sub>10</sub> of thermoTRP channels in living cells

Ito

Ikemoto

Yoshioka

2015

BIOPHYSICS

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The activity of thermo-transient receptor potential (TRP) channels is highly dependent on temperature, and thus thermo-TRP reactions have a high temperature coefficient Q10. In thermodynamics, a high value of Q10 indicates the existence of a large activation energy (i.e., a large enthalpy) over a short period during the transition process between the closed and open states of the channels. The Gibbs free energy equation shows that a large entropy is required to compensate for this large enthalpy and permit activation of the channels, suggesting a large conformational change of the channels. These large values of enthalpy and entropy seem to be a match for the values of the unfolding process of globular proteins. We outline these thermodynamic issues in thermo-TRPs.

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Handshake request motion model with an approaching human for a handshake robot system

Jindai

Ota

Ikemoto

et al. 2015

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Development of a human‐tissue‐like phantom for 3.0‐T MRI

et al. 2011

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Adjustment of GdCl(3) and agarose concentrations allows arbitrary setting of relaxation times, and the creation of a phantom that can mimic relaxation times of human-tissue. Carrageenan is considered the most suitable as a gelling agent for an MRI phantom, as it permits the relatively easy and inexpensive production of a large phantom such as for the human torso, and which can be easily shaped with a knife.

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Bio-inspired Tensegrity Fish Robot

Shintake

Zappetti

Peter

et al. 2020

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Yusuke Ikemoto

Development of MRI phantom equivalent to human tissues for 3.0‐T MRI

Thermodynamic implications of high <i>Q</i><sub>10</sub> of thermoTRP channels in living cells

Handshake request motion model with an approaching human for a handshake robot system

Development of a human‐tissue‐like phantom for 3.0‐T MRI

Bio-inspired Tensegrity Fish Robot

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