Litcius/Paper detail

On-chip on-demand delivery of K+ for <i>in vitro</i> bioelectronics

Harika Dechiraju, John Selberg, Manping Jia, Pattawong Pansodtee, Houpu Li, Hao‐Chieh Hsieh, Cristian Hernandez, Narges Asefifeyzabadi, Tiffany Nguyen, Prabhat Baniya, Giovanny Marquez, Cody R. Rasmussen-Ivey, Carrie Bradley, Mircea Teodorescu, Marcella Gomez, Michael Levin, Marco Rolandi

2022AIP Advances15 citationsDOIOpen Access PDF

Abstract

Bioelectronic devices that interface electronics with biological systems can actuate and control biological processes. The potassium ion plays a vital role in cell membrane physiology, maintaining the cell membrane potential (Vmem) and generating action potentials. In this work, we present two bioelectronic ion pumps that use an electronic signal to modulate the potassium ion concentration in solution. The first ion pump is designed to integrate directly with six-well cell culture plates for optimal ease of integration with in vitro cell culture, and the second on-chip ion pump provides high spatial resolution. These pumps offer increased ease of integration with in vitro systems and demonstrate K+ concentration distribution with high spatial resolution. We systematically investigate the ion pump’s performance using electrical characterization and computational modeling, and we explore closed-loop control of K+ concentration using fluorescent dyes as indicators. As a proof-of-concept, we study the effects of modulating K+ concentration on Vmem of THP-1 macrophages.

Topics & Concepts

BioelectronicsNanotechnologyElectronicsIonMembrane potentialChipChemistryIn vitroMembraneMaterials scienceBiophysicsBiological systemComputer scienceBiosensorBiochemistryBiologyPhysical chemistryTelecommunicationsOrganic chemistryNeuroscience and Neural EngineeringAdvanced Sensor and Energy Harvesting MaterialsAnalytical Chemistry and Sensors