Detail of Fig4B



Project
Title
BDML file for quantiative information about the contractile force of the muscle of Earthworm
Description
NA
Release, Updated
2018-11-15
License
CC BY
Kind
Quantitative data based on Experiment
File Formats
Data size
136.3 MB

Organism
M. sieboldi ( NCBI:txid506672 )
Strain(s)
-
Cell Line
-

Datatype
Muscle dynamics
Molecular Function (MF)
Biological Process (BP)
-
Cellular Component (CC)
-
Biological Imaging Method
XYZ Scale
-
T scale
20 second for each time interval

Image Acquisition
Experiment type
-
Microscope type
-
Acquisition mode
-
Contrast method
-
Microscope model
-
Detector model
-
Objective model
-
Filter set
-

Summary of Methods
See details in Tanaka et al. (2017) Sens Actuators B Chem, 242: 1186-1192.
Related paper(s)

Tanaka, Yo, Noguchi, Yuji, Yalikun, Yaxiaer, Kamamichi, Norihiro (2017), Earthworm muscle driven bio-micropump, Sensors and Actuators B: Chemical, Volume 242, 1186-1192

Published in 2017/04/01/

(Abstract) Research on fusing microdevices and cellular mechanical functions to construct bio-microactuators has attracted attention because these bio-microactuators use a novel principle that exploits cellular size and capabilities. Compared with biological components available until now, the natural muscle of earthworms is an excellent actuator to drive fluids due to its membranous structure, strong force, short response time, and controllability. Here, the mechanical performance of earthworm muscle as an actuator component was investigated, and a micropump was successfully demonstrated combining the muscle with microchips triggered by a DC power supply. The maximum generated force was about 9.33 mN, and dead time and rise time (response time) were 104±15ms and 245±31ms, respectively. The stroke volume and vertical direction diaphragm displacement were calculated as 9.3μL and 1.2mm, respectively, when a 4mm diameter chamber was used. The directional flow rate using check valves was estimated to be about 5.0μL/min (at 0.3Hz) which is about 3–4 orders higher than that for a similar type of cardiomyocyte pump reported previously. By exploiting the natural earthworm muscle, performance items such as flow rate, force, and response time approached those of conventional pumps including piezoelectric, dielectric material, and IPMC-based pumps. This is the first demonstration to use earthworm muscle as an actuator for a microfluidic system which can be a model to create a sophisticated cell-based actuator.

Contact
Yo Tanaka , RIKEN , Quantitative Biology Center , Laboratory for Integrated Biodevice
Contributors
Yo Tanaka, Yuji Noguchi, Yaxiaer Yalikun, Norihiro Kamamichi

Local ID
Fig4B
BDML ID
fa0cda19-8637-4b69-86fa-a5e2e20a3830
BDML/BD5