Objective: To clarify whether tumor necrosis factor (TNF)-alpha modulates the inhibitory effect of clinically applied hypnotics and sedatives on neutrophil function.
Design: Prospective, randomized, controlled, dose response, in vitro study.
Setting: A university research laboratory.
Subjects: Neutrophils from healthy human volunteers.
Measurements and main results: Neutrophils were primed by incubation with TNF-alpha (25 ng/mL) for 15 mins. Subsequently, TNF-alpha-primed neutrophils were incubated with two concentrations of commercially available drug preparations and drug-free solutions, respectively. The following commercially available preparations of hypnotics and sedatives as well as their corresponding drug-free solutions were tested: methohexital, thiopental, midazolam, diazepam, etomidate, and propofol. The production of oxygen radicals was initiated by adding N-formyl-methionyl-leucyl-phenylalanine (FMLP) 10(-7) mol/L and detected by luminol-enhanced chemiluminescence measurements for 15 mins. Within the range of therapeutic plasma concentrations, only thiopental, diazepam, and propofol suppressed chemiluminescence of unprimed neutrophils. Additionally, propofol alone suppressed TNF-alpha-primed neutrophils. Hypnotics and sedatives were unable to suppress oxygen radical production of TNF-alpha-primed neutrophils below the level of their control activity, measured in FMLP-induced unprimed neutrophils in the absence of the respective drug or drug-free solution. However, the effect of etomidate could not be evaluated secondarily to effects mediated by its drug-free solution. In a cell-free chemiluminescence system, thiopental and propofol demonstrated scavenging of oxygen free radicals.
Conclusions: Priming with TNF-alpha counteracts the inhibitory effect by certain drugs for oxygen radical formation by FMLP-stimulated neutrophils. Thus, TNF-alpha plus FMLP mediate additive effects in stimulating oxygen radical formation in neutrophils. The following drugs dose-dependently interfere with these activating pathways: thiopental, diazepam, and propofol. Additionally, thiopental and propofol have efficient oxygen-scavenging properties and may attenuate radical-mediated tissue destruction in hyperinflammatory syndromes.