Formation of long-lived reactive products in blood serum under heat treatment and low-intensity laser irradiation, their role in hydrogen peroxide generation and DNA damage

Long-lived reactive protein products were shown to be evolved under heat treatment and low-intensity laser irradiation in blood serum in presence of dissolved oxygen from the air. These reactive protein products generate hydrogen peroxide for a long time, which results from conjugated electron-radical chain reactions. Long-lived reactive protein species play an important role in the adaptation of living systems to stress factors. Apparently, the formation of visible light- and heat-induced reactive protein species is not specific to just blood serum proteins, rather than it could also be a feature of other proteins

Formation of long-lived reactive products in blood serum under heat treatment and low-intensity laser irradiation, their role in hydrogen peroxide generation and DNA damage

214-223Long-lived reactive protein products were shown to be evolved under heat treatment and low-intensity laser irradiation in blood serum in presence of dissolved oxygen from the air. These reactive protein products generate hydrogen peroxide for a long time, which results from conjugated electron-radical chain reactions. Long-lived reactive protein species play an important role in the adaptation of living systems to stress factors. Apparently, the formation of visible light- and heat-induced reactive protein species is not specific to just blood serum proteins, rather than it could also be a feature of other proteins

Control over phase separation and nucleation using a laser-tweezing potential

Control over the nucleation of new phases is highly desirable but elusive. Even though there is a long history of crystallization engineering by varying physicochemical parameters, controlling which polymorph crystallizes or whether a molecule crystallizes or forms an amorphous precipitate is still a poorly understood practice. Although there are now numerous examples of control using laser-induced nucleation, the absence of physical understanding is preventing progress. Here we show that the proximity of a liquid–liquid critical point or the corresponding binodal line can be used by a laser-tweezing potential to induce concentration gradients. A simple theoretical model shows that the stored electromagnetic energy of the laser beam produces a free-energy potential that forces phase separation or triggers the nucleation of a new phase. Experiments in a liquid mixture using a low-power laser diode confirm the effect. Phase separation and nucleation using a laser-tweezing potential explains the physics behind non-photochemical laser-induced nucleation and suggests new ways of manipulating matter