Microfluidic Cardiac Cell Culture Model (μCCCM)

Physiological heart development and cardiac function rely on the response of cardiac cells to mechanical stress during hemodynamic loading and unloading. These stresses, especially if sustained, can induce changes in cell structure, contractile function, and gene expression. Current cell culture tec...

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Bibliographic Details
Published in:Analytical chemistry (Washington) 2010-09, Vol.82 (18), p.7581-7587
Main Authors: Giridharan, Guruprasad A, Nguyen, Mai-Dung, Estrada, Rosendo, Parichehreh, Vahidreza, Hamid, Tariq, Ismahil, Mohamed Ameen, Prabhu, Sumanth D, Sethu, Palaniappan
Format: Article
Language:English
Subjects:
Analytical chemistry
Biological and medical sciences
Blood Pressure
Cardiomyocytes
Cell Culture Techniques - instrumentation
Cell Line
Cells
Fundamental and applied biological sciences. Psychology
Gene expression
Heart
Heart - physiology
Microfluidic Analytical Techniques
Molecular and cellular biology
Molecular genetics
Myocytes, Cardiac - cytology
Myocytes, Cardiac - physiology
Physiology
Replication
Stress, Mechanical
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Summary:Physiological heart development and cardiac function rely on the response of cardiac cells to mechanical stress during hemodynamic loading and unloading. These stresses, especially if sustained, can induce changes in cell structure, contractile function, and gene expression. Current cell culture techniques commonly fail to adequately replicate physical loading observed in the native heart. Therefore, there is a need for physiologically relevant in vitro models that recreate mechanical loading conditions seen in both normal and pathological conditions. To fulfill this need, we have developed a microfluidic cardiac cell culture model (μCCCM) that for the first time allows in vitro hemodynamic stimulation of cardiomyocytes by directly coupling cell structure and function with fluid induced loading. Cells are cultured in a small (1 cm diameter) cell culture chamber on a thin flexible silicone membrane. Integrating the cell culture chamber with a pump, collapsible pulsatile valve and an adjustable resistance element (hemostatic valve) in series allow replication of various loading conditions experienced in the heart. This paper details the design, modeling, fabrication and characterization of fluid flow, pressure and stretch generated at various frequencies to mimic hemodynamic conditions associated with the normal and failing heart. Proof-of-concept studies demonstrate successful culture of an embryonic cardiomyoblast line (H9c2 cells) and establishment of an in vivo like phenotype within this system.
ISSN:0003-2700
1520-6882
DOI:10.1021/ac1012893