by Keyword: Spleen

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Rigat, L., Elizalde, A., Del Portillo, H. A., Homs-Corbera, A., Samitier, J., (2014). Selective cell culturing step using laminar co-flow to enhance cell culture in splenon-on-a-chip biomimetic platform MicroTAS 2014 18th International Conference on Miniaturized Systems for Chemistry and Life Sciences , CBMS (San Antonio, USA) , 769-771

Constant evolution and improvements on areas such as tissue engineering, microfluidics and nanotechnology have made it possible to partially close the gap between conventional in vitro cell cultures and animal model-based studies. A step forward in this field concerns organ-on-chip technologies, capable of reproducing the most relevant physiological features of an organ in a microfluidic platform. In this work we have exploited the capabilities of laminar co-flow inside our biomimetic platform, the splenon-on-a-chip, in order to enhance cell culture inside its channels to better mimic the spleen's environment. © 14CBMS.

Keywords: Cell culture, Co-flow, Laminar flow, Organ-on-a-chip, Spleen

Rigat, L., Bernabeu, M., Elizalde, A., de Niz, M., Martin-Jaular, L., Fernandez-Becerra, C., Homs-Corbera, A., del Portillo, H. A., Samitier, J., (2014). Human splenon-on-a-chip: Design and validation of a microfluidic model resembling the interstitial slits and the close/fast and open/slow microcirculations IFMBE Proceedings XIII Mediterranean Conference on Medical and Biological Engineering and Computing 2013 (ed. Roa Romero, Laura M.), Springer (Seville, Spain) 41, 884-887

Splenomegaly, albeit variably, is a landmark of malaria infection. Due to technical and ethical constraints, however, the role of the spleen in malaria remains vastly unknown. The spleen is a complex three-dimensional branched vasculature exquisitely adapted to perform different functions containing closed/rapid and open/slow microcirculations, compartmentalized parenchyma (red pulp, white pulp and marginal zone), and sinusoidal structure forcing erythrocytes to squeeze through interstitial slits before reaching venous circulation. Taking into account these features, we have designed and developed a newfangled microfluidic device of a human splenon-on-a-chip (the minimal functional unit of the red pulp facilitating blood-filtering and destruction of malarial-infected red blood cells). Our starting point consisted in translating splenon physiology to the most similar microfluidic network, mimicking the hydrodynamic behavior of the organ, to evaluate and simulate its activities, mechanics and physiological responses and, therefore, enable us to study biological hypotheses. Different physiological features have been translated into engineering elements that can be combined to integrate a biomimetic microfluidic spleen model. The device is fabricated in polydimethylsiloxane (PDMS), a biocompatible polymer, irreversibly bonded to glass. Microfluidics analyses have confirmed that 90% of the blood circulates through a fast-flow compartment whereas the remaining 10% circulates through a slow compartment, equivalently to what has been observed in a real spleen. Moreover, erythrocytes and reticulocytes going through the slow-flow compartment squeeze at the end of it through 2μm physical constraints resembling interstitial slits to reach the closed/rapid circulation.

Keywords: Malaria, Microfluidics, Organ-on-a-chip, Spleen