Many important observations and discoveries in heart physiology have been made possible using the isolated heart method of Langendorff, e.g. the discovery of the very famous Frank-Starling law of the heart. Nevertheless, the Langendorff’s method has some limitations and disadvantages such as the probability of preconditioning and a high oxidative stress, leading to the deterioration of the contractile function. To avoid the preceding drawbacks associated to the use of a whole heart, we have alternatively used beating mouse cardiac syncytia cultured in vitro in order to assess the ergotropic and chronotropic effects of both increasing and decreasing hydrostatic pressures. To achieve the preceding aim, we have developed a method based on image processing analysis to evaluate the kinematics of that pressure-loaded beating syncytia starting from the video registration of their contraction movement. We have verified the Frank-Starling law of the heart in in vitro beating cardiac syncytia and we have obtained their geometrical-functional classification. The present method could be used in in vitro studies of beating cardiac patches, as alternative to the Langendorff’s heart in biochemical, pharmacological, and physiology studies, and, especially, when the Langendorff’s technique is inapplicable. Furthermore, the method could help, in heart tissue engineering and bioartificial heart researches, to “engineer the heart piece by piece”.

Effects of the hydrostatic pressure in in vitro beating cardiac syncytia in terms of kinematics (kinetic energy and beat frequency) and syncytia geometrical-functional classification

Fassina L;Cusella De Angelis MG;Sardi F;Magenes G.
2013-01-01

Abstract

Many important observations and discoveries in heart physiology have been made possible using the isolated heart method of Langendorff, e.g. the discovery of the very famous Frank-Starling law of the heart. Nevertheless, the Langendorff’s method has some limitations and disadvantages such as the probability of preconditioning and a high oxidative stress, leading to the deterioration of the contractile function. To avoid the preceding drawbacks associated to the use of a whole heart, we have alternatively used beating mouse cardiac syncytia cultured in vitro in order to assess the ergotropic and chronotropic effects of both increasing and decreasing hydrostatic pressures. To achieve the preceding aim, we have developed a method based on image processing analysis to evaluate the kinematics of that pressure-loaded beating syncytia starting from the video registration of their contraction movement. We have verified the Frank-Starling law of the heart in in vitro beating cardiac syncytia and we have obtained their geometrical-functional classification. The present method could be used in in vitro studies of beating cardiac patches, as alternative to the Langendorff’s heart in biochemical, pharmacological, and physiology studies, and, especially, when the Langendorff’s technique is inapplicable. Furthermore, the method could help, in heart tissue engineering and bioartificial heart researches, to “engineer the heart piece by piece”.
2013
Proceedings of the Annual International Conference of the IEEE Engineering in Medicine and Biology Society
9781457702167
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11571/701819
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