Incubator system that directly measures and controls pericellular oxygen levels enabling precise regulation of the cellular microenvironment
Background:
Cell culture is a fundamental technique in biomedical research that aims to replicate physiological conditions for cellular studies. While oxygen is a critical factor affecting cell behaviour and physiology, current oxygen-controlling technologies focus on regulating gas-phase oxygen levels through nitrogen flushing. However, recent research has revealed that the actual oxygen concentration cells experience (pericellular oxygen) differs significantly from the surrounding gas phase concentration. This discrepancy, caused by cellular oxygen consumption, leads to inconsistent experimental conditions and unreliable results. Traditional oxygen control systems fail to account for these variations in pericellular oxygen levels, creating a critical gap in cell culture technology.
Technical Overview:
Northeastern researchers have developed an innovative cell culture incubator that directly measures and controls pericellular oxygen concentration rather than gas-phase oxygen levels. The system employs pericellular oxygen sensors as feedback mechanisms to regulate nitrogen or air flux, ensuring cells experience consistent oxygen levels regardless of variables such as cell type, density, or culture conditions. This approach represents a fundamental shift from conventional gas phase control methods, enabling precise regulation of the actual oxygen concentration that cells experience. The technology has demonstrated proof-of-concept validation, showing the ability to maintain consistent pericellular oxygen levels across varying experimental conditions.
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