Litcius/Paper detail

MyoLoop: Design, development and validation of a standalone bioreactor for pathophysiological electromechanical in vitro cardiac studies

Fotios G. Pitoulis, J J Smith, Blanca Pamias‐Lopez, Pieter P. de Tombe, Danika Hayman, Cesare M. Terracciano

2023Experimental Physiology12 citationsDOIOpen Access PDF

Abstract

Mechanical load is one of the main determinants of cardiac structure and function. Mechanical load is studied in vitro using cardiac preparations together with loading protocols (e.g., auxotonic, isometric). However, such studies are often limited by reductionist models and poorly simulated mechanical load profiles. This hinders the physiological relevance of findings. Living myocardial slices have been used to study load in vitro. Living myocardial slices (LMS) are 300-μm-thick intact organotypic preparations obtained from explanted animal or human hearts. They have preserved cellular populations and the functional, structural, metabolic and molecular profile of the tissue from which they are prepared. Using a three-element Windkessel (3EWK) model we previously showed that LMSs can be cultured while performing cardiac work loops with different preload and afterload. Under such conditions, LMSs remodel as a function of the mechanical load applied to them (physiological load, pressure or volume overload). These studies were conducted in commercially available length actuators that had to be extensively modified for culture experiments. In this paper, we demonstrate the design, development and validation of a novel device, MyoLoop. MyoLoop is a bioreactor that can pace, thermoregulate, acquire and process data, and chronically load LMSs and other cardiac tissues in vitro. In MyoLoop, load is parametrised using a 3EWK model, which can be used to recreate physiological and pathological work loops and the remodelling response to these. We believe MyoLoop is the next frontier in basic cardiovascular research enabling reductionist but physiologically relevant in vitro mechanical studies.

Topics & Concepts

PreloadAfterloadBiomedical engineeringMechanical loadIn vitroIn vivoCardiac function curveBiologyCardiologyMedicineMaterials scienceHemodynamicsBiochemistryHeart failureBiotechnologyComposite materialTissue Engineering and Regenerative MedicineElectrospun Nanofibers in Biomedical Applications3D Printing in Biomedical Research
MyoLoop: Design, development and validation of a standalone bioreactor for pathophysiological electromechanical in vitro cardiac studies | Litcius