Measuring Single Cardiac Myocyte Contractile Force via Moving a Magnetic Bead

Yin, Shizhuo; Zhang, Xueqian; Zhan, Chun; Wu, Juntao; Xu, Jinchao; Cheung, Joseph Y.

doi:10.1529/biophysj.104.048157

Cited by 69 publications

(53 citation statements)

References 17 publications

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“…Model developments: Based on the published experimental results [2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18] , we approximately consider, BF in SR, cells or extra-cells, as quasi liquid plasmas in physics, the plasmas are quasi neutral electromagnetically; biological or biochemical components such as free Ca++ in BF, SR SubMembrane (SRSM) or Cell Membrane (CM), Ca++H+ (Ca++ or Na+K+) ATPases, NCX, Ca++ carriers and myosin heads, because disturbances, internal excitations or external stimulations always exist, often are displaced from their equilibrium positions or distances, the redistribution of charges and masses will respectively set up forces, tensions or pressures at the components. The forces, the tensions or the pressures will restore the components back to their original equilibrium positions or distances and could initiate a vibration (oscillation), even a resonance.…”

Section: Methodsmentioning

confidence: 99%

“…Scientists have studied the mechanisms for more than 100 years [2,3] and proposed models for the mechanisms. The models respectively involved mathematics [4,5] , biophysics [6,7] , biochemistry [8][9][10][11][12][13][14][15][16][17][18] . But, none involved the automation of the vibrations (oscillations) [2] .…”

Section: Introductionmentioning

confidence: 99%

“…In this investigation, based on published data or results [2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18] , conservation laws of the momentum as well as the energy, in views of biology, biochemistry, informatics and physics (BioChemInfoPhysics), we proposed models of cardiac cellular and sub-cellular vibrations (oscillations) of biological components, such as free ions in Biological Fluids (BF), Biological Membranes (BM), Ca++H+ (Ca++ and Na+K+) ATPases, Na+Ca++ exchangers (NCX), Ca++ carriers and myosin heads. Moreover, we discuss our models' general applications and general meanings in biology.…”

Section: Introductionmentioning

confidence: 99%

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Four Dimensional (4-D) BioChemInfoPhysics Models of Cardiac Cellular and Sub-Cellular Vibrations (Oscillations)

Cheng¹,

Zou²

2009

OnLine J. of Biological Sciences

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Problem statement: Cardiovascular Diseases (CVD) continued to be the leading cause of death. Failure or abnormal cardiac cellular or sub-cellular vibrations (oscillations) could lead failure or abnormal heart beats that could cause CVD. Understanding the mechanisms of the vibrations (oscillations) could help to prevent or to treat the diseases. Scientists have studied the mechanisms for more than 100 years. To our knowledge, the mechanisms are still unclear today. In this investigation, based on published data or results, conservation laws of the momentum as well as the energy, in views of biology, biochemistry, informatics and physics (BioChemInfoPhysics), we proposed our models of cardiac cellular and sub-cellular vibrations (oscillations) of biological components, such as free ions in Biological Fluids (BF), Biological Membranes (BM), Ca++H+ (Ca++ and Na+K+) ATPases, Na+Ca++ exchangers (NCX), Ca++ carriers and myosin heads. Approach: Our models were described with 4-D (x, y, z, t or r, θ, z, t) momentum transfer equations in mathematical physics. Results: The momentum transfer equations were solved with free and forced, damped, un-damped and over-damped, vibrations (oscillations). The biological components could be modeled as resonators or vibrators (oscillators), such as liquid plasmas, membranes, active springs, passive springs and active swings.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Four Dimensional (4-D) BioChemInfoPhysics Models of Cardiac Cellular and Sub-Cellular Vibrations (Oscillations)

Cheng¹,

Zou²

2009

OnLine J. of Biological Sciences

View full text Add to dashboard Cite

show abstract

“…Some heart diseases that can damage the normal contraction and relaxation behavior of heart cells, even in the early stages (2), may result from differences in contractile forces and mechanical properties between healthy and diseased cells. Therefore, analyzing the contractile force, mechanical properties, and dynamic beating behavior of heart cells is of great significance for the quantitative understanding of the mechanism of heart disease and the molecular alterations that occur in diseased heart cells (3). Moreover, cardiomyocytes have been used as actuators in the development of bio-syncretic robots in recent years (4)(5)(6)(7)(8)(9) for their advantageous functional features, including spontaneous contraction, high energy conversion efficiency, and high energy density (10).…”

Section: Introductionmentioning

confidence: 99%

“…The stretching method is the most direct measuring approach. This method is implemented by holding onto both ends of a cell with microclamps, beads, or hooks, and then measuring the contractility of the living beating cell (3,24,25). Another simple method is to use a micrometer-scale, elastic pillar array as a substrate to culture heart cells.…”

Section: Introductionmentioning

confidence: 99%

Dynamic Model for Characterizing Contractile Behaviors and Mechanical Properties of a Cardiomyocyte

Zhang

Wang

et al. 2018

Biophysical Journal

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Studies on the contractile dynamics of heart cells have attracted broad attention for the development of both heart disease therapies and cardiomyocyte-actuated micro-robotics. In this study, a linear dynamic model of a single cardiomyocyte cell was proposed at the subcellular scale to characterize the contractile behaviors of heart cells, with system parameters representing the mechanical properties of the subcellular components of living cardiomyocytes. The system parameters of the dynamic model were identified with the cellular beating pattern measured by a scanning ion conductance microscope. The experiments were implemented with cardiomyocytes in one control group and two experimental groups with the drugs cytochalasin-D or nocodazole, to identify the system parameters of the model based on scanning ion conductance microscope measurements, measurement of the cellular Young's modulus with atomic force microscopy indentation, measurement of cellular contraction forces using the micro-pillar technique, and immunofluorescence staining and imaging of the cytoskeleton. The proposed mathematical model was both indirectly and qualitatively verified by the variation in cytoskeleton, beating amplitude, and contractility of cardiomyocytes among the control and the experimental groups, as well as directly and quantitatively validated by the simulation and the significant consistency of 90.5% in the comparison between the ratios of the Young's modulus and the equivalent comprehensive cellular elasticities of cells in the experimental groups to those in the control group. Apart from mechanical properties (mass, elasticity, and viscosity) of subcellular structures, other properties of cardiomyocytes have also been studied, such as the properties of the relative action potential pattern and cellular beating frequency. This work has potential implications for research on cytobiology, drug screening, mechanisms of the heart, and cardiomyocyte-based bio-syncretic robotics.

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Fabrication and Functionality Integration Technologies for Small‐Scale Soft Robots

Zhang

Qin

et al. 2022

Advanced Materials

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Small‐scale soft robots are attracting increasing interest for visible and potential applications owing to their safety and tolerance resulting from their intrinsic soft bodies or compliant structures. However, it is not sufficient that the soft bodies merely provide support or system protection. More importantly, to meet the increasing demands of controllable operation and real‐time feedback in unstructured/complicated scenarios, these robots are required to perform simplex and multimodal functionalities for sensing, communicating, and interacting with external environments during large or dynamic deformation with the risk of mismatch or delamination. Challenges are encountered during fabrication and integration, including the selection and fabrication of composite/materials and structures, integration of active/passive functional modules with robust interfaces, particularly with highly deformable soft/stretchable bodies. Here, methods and strategies of fabricating structural soft bodies and integrating them with functional modules for developing small‐scale soft robots are investigated. Utilizing templating, 3D printing, transfer printing, and swelling, small‐scale soft robots can be endowed with several perceptual capabilities corresponding to diverse stimulus, such as light, heat, magnetism, and force. The integration of sensing and functionalities effectively enhances the agility, adaptability, and universality of soft robots when applied in various fields, including smart manufacturing, medical surgery, biomimetics, and other interdisciplinary sciences.

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Measuring Single Cardiac Myocyte Contractile Force via Moving a Magnetic Bead

Cited by 69 publications

References 17 publications

Four Dimensional (4-D) BioChemInfoPhysics Models of Cardiac Cellular and Sub-Cellular Vibrations (Oscillations)

Four Dimensional (4-D) BioChemInfoPhysics Models of Cardiac Cellular and Sub-Cellular Vibrations (Oscillations)

Dynamic Model for Characterizing Contractile Behaviors and Mechanical Properties of a Cardiomyocyte

Fabrication and Functionality Integration Technologies for Small‐Scale Soft Robots

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