Validation of a VerifyNow-P2Y12 cartridge for monitoring platelet inhibition with clopidogrel.

Despite common use of clopidogrel in patients with vascular disease, monitoring of platelet inhibition is still not conventional in clinical practice. Considering substantial response variability, when some patients may experience inadequate protection, and/or increased risk of bleeding, simple and reliable methods to control adequate antiplatelet regimen is mandatory. We validated a new VerifyNow-P2Y12 assay to measure inhibition of the P2Y12 platelet receptors by clopidogrel by evaluating its receptor specificity, precision, and potential interference with platelet count, hematocrit, age, cholesterol, triglycerides, and other antiplatelet agents. Platelet aggregation induced by ADP or ADP + prostaglandin E1 (ADP + PGE1) in the presence of specific P2Y12 inhibitor 2-methylthio-AMP (2MeSAMP) for the assessment of assay specificity was performed in 10 volunteers. Seventeen medications were used for the VerifyNow-P2Y12 interference testing, and assay interplay with blood constituents was evaluated in a clinical setting in 131 patients with coronary artery disease. In the presence of 2MeSAMP, the average residual aggregation level across the 10 donors was 27% for ADP and 5% for ADP + PGE1. There also was a strong agreement between ADP + PGE1 aggregometry and VerifyNow-P2Y12 assay (93% vs. 95% average inhibition across all donors). The coefficient of variation for the test precision was less than 8%. The VerifyNow-P2Y12 readings were not influenced by age, platelet count, hematocrit, fibrinogen, cholesterol, or triglycerides level. There was an interference with abciximab before P2Y12 inhibition; however, after platelet suppression with cilostazol, the interference with all tested substances was minimal. VerifyNow-P2Y12 is a reliable, simple, and sensitive device suitable for monitoring of P2Y12 platelet receptor inhibitors in the clinical arena.

Criticality of pH for accurate fluorometric measurements of dipyridamole levels in biological fluids.

Extended release dipyridamole (DIP) is widely used in clinical practice as an Aggrenox formulation, which is proven to improve outcomes for secondary stroke prevention in patients after acute vascular events. However, presently established fluorometry techniques are not suitable for trace amount determinations, because of the variable background fluorescence. The authors sought to determine whether biological fluid pH is important for the serial measures of DIP levels in the animal experiments and in patients treated with Aggrenox after ischemic stroke. Post-stroke patient (n = 34) and mice (n = 25) samples were tested to determine DIP levels by established techniques with FluoroMax 3 spectrofluorometer. Both the absorption and emission spectra of DIP were affected by modifications in pH. Fluorescence of DIP was found to be maximal at a wavelength of 490 nm (excitation 420 nm) and the spectral pattern was independent of pH. The intensity of fluorescence, however, was drastically lower at low pH (at pH 2.6, fluorescence was 4% of intensity at pH 9.8). Background plasma fluorescence, however, was completely unaffected by changes in pH. Using these fluorometric characteristics, a regression model that facilitates the efficient and sensitive determination of DIP concentration in biological fluids was formulated. Exploiting pH-dependent characteristics of DIP versus serum fluorescence patterns permits a convenient mathematical model to determine DIP concentration. This relatively inexpensive and time-efficient procedure can quantify drug levels in human/animal plasma/serum, thereby directly determining the level of patient adherence to the prescribed drug regimen, be it in the context of clinical trials or compliance with the animal protocol.