Thermal nonlinear optical responses of native and oxidized low-density lipoprotein solutions at visible and infra-red wavelengths: complementary approaches

Abstract

Single beam Z-scan (ZS) experiments at 532 nm (visible) and 979 nm [infra-red (IR)] wavelengths were used to determine photothermal responses of native and oxidized aqueous suspensions of human low-density lipoproteins (LDLs). The wavelengths employed in the measurements were chosen according to the optical absorption solute (LDL particles) and solvent (water) of the suspension. At 532 nm, water presents negligible absorbance, and the LDL is responsible for the light absorption. On the other hand, at 979 nm, the water is the main light absorber. In the visible light case, the particles absorb the laser light and, by conduction, transfer heat to water to form the thermal lens. In the IR experiments, water is the main absorber and transfers the heat to the particles to form the thermal lens. We show that with the IR light it is possible to investigate high degrees of oxidation of LDL, not possible with the usual visible light experiments. Differently from the usual ZS experiments with LDL at visible light, the magnitude of the thermal lens formed in the IR experiments was shown to be bigger in oxidized samples with respect to that of the native samples. For both wavelengths, all samples whose response was measured presented negative nonlinearity (self-defocusing behavior). It was also observed, in experiments with IR light, that the formation time of the thermal lens tends to decrease with the increase in the degree of oxidation of the sample.