Fiber-optic biosensor to assess circulating phagocyte activity by chemiluminescence.

We describe herein the construction of a novel computerized multi-sample temperature-controlled luminometer for a fiber array-based biosensor to monitor circulating phagocyte activity. It can perform simultaneously integral measurements of chemiluminescence emitted from up to six samples containing less than 0.5 microl whole blood while the samples and detector do not change their position during the measurement cycle.

Functional states of polymorphonuclear leukocytes determined by chemiluminescent kinetic analysis.

During the respiratory burst, upon stimulation with both soluble and particulate matter, polymorphonuclear leukocytes (PMN) generate reactive oxygen species (ROS) and emit chemiluminescence (CL) as a result of metabolic activation. The measurement of CL has been demonstrated to be a useful tool for in vitro assessment of the opsonophagocytic function of PMN. Using component analysis of CL kinetics, we characterized the functional state of PMN by three parameters of the respiratory burst: capacity, effectiveness and velocity (CEV space).

Model components of luminol chemiluminescence generated by PMNL.

The production of activated oxygen species (AOS) by neutrophils (PMNL) is thought to play a key role in the host defence against invading microorganisms. However, the oxygen metabolites are toxic not only to the invading bacteria but also to the surrounding tissue. The oxidative metabolites production can be evaluated by means of chemiluminescent methods.

A new approach for analysis of chemiluminescent kinetics of activated phagocytes in blood.

Luminol chemiluminescence (LCL) is a simple, sensitive and time-saving tool to elucidate the oxidative activity of polymorphonuclear leukocytes (PMNL). In this study, a new approach for analysing the LCL kinetics, recorded from stimulated PMNL, and for a more accurate elucidation of their functional state, is proposed. This approach is based on the proposal that the LCL kinetics of stimulated PMNL is a result of time-probabilistic nature of the processes, leading to light emission.