In vitro arrhythmia generation by mild hypothermia: a pitchfork bifurcation type process

The neurological damage after cardiac arrest presents a huge challenge for hospital discharge. Therapeutic hypothermia (34 degrees C - 32 degrees C) has shown its benefits in reducing cerebral oxygen demand and improving neurological outcomes after cardiac arrest. However, it can have many adverse effects, among them cardiac arrhythmia generation which represents an important part (up to 34%, according different clinical studies). A monolayer cardiac culture is prepared with cardiomyocytes from a newborn rat, directly on a multi-electrode array, which allows the acquisition of the extracellular potential of the culture. The temperature range is 37 degrees C - 30 degrees C-37 degrees C, representing the cooling and rewarming process of therapeutic hypothermia. Experiments showed that at 35 degrees C, the acquired signals are characterized by period-doubling phenomenon, compared with signals at other temperatures. Spiral waves, commonly considered to be a sign of cardiac arrhythmia, are observed in the reconstructed activation map. With an approach from nonlinear dynamics, phase space reconstruction, it is shown that at 35 degrees C, the trajectories of these signals formed a spatial bifurcation, even trifurcation. Another transit point is found between 30 degrees C-33 degrees C, which agreed with other clinical studies that induced hypothermia after cardiac arrest should not fall below 32 degrees C. The process of therapeutic hypothermia after cardiac arrest can be represented by a pitchfork bifurcation type process, which could explain the different ratios of arrhythmia among the adverse effects after this therapy. This nonlinear dynamic suggests that a variable speed of cooling/rewarming, especially when passing 35 degrees C, would help to decrease the ratio of post-hypothermia arrhythmia and then improve the hospital output.