Enhanced myocyte-based biosensing of the blood-borne signals regulating chronotropy

doi:10.1152/japplphysiol.00672.2001

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J Appl Physiol 92: 581-585, 2002. First published October 26, 2001; doi:10.1152/japplphysiol.00672.2001
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Vol. 92, Issue 2, 581-585, February 2002

Enhanced myocyte-based biosensing of the blood-borne signals regulating chronotropy

Jay M. Edelberg¹^,², Jason T. Jacobson¹, David S. Gidseg⁴, Lilong Tang¹, and David J. Christini¹^,³

Departments of ¹ Medicine, ² Cell Biology, and ³ Physiology and Biophysics, ⁴ Weill Medical College of Cornell University, New York, New York 10021

Biosensors play a critical role in the real-time determination of relevant functional physiological needs. However, typicalin vivo biosensors only approximate endogenous function via themeasurement of surrogate signals and, therefore, may often lacka high degree of dynamic fidelity with physiological requirements.To overcome this limitation, we have developed an excitable tissue-basedimplantable biosensor approach, which exploits the inherent electropotentialinput-output relationship of cardiac myocytes to measure the physiologicalregulatory inputs of chronotropic demand via the detection ofblood-borne signals. In this study, we report the improvementof this application through the modulation of host-biosensor communicationvia the enhancement of vascularization of chronotropic complexesin mice. Moreover, in an effort to further improve translationalapplicability as well as molecular plasticity, we have advancedthis approach by employing stem cell-derived cardiac myocyte aggregatesin place of whole cardiac tissue. Overall, these studies demonstratethe potential of biologically based biosensors to predict endogenousphysiological dynamics and may facilitate the translation of thisapproach for in vivomonitoring.

biosensor; tissue engineering; stem cell; pacemaker; cardiac myocyte

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