M De la Fuente I , Malaina I , Pérez-Samartín A , Boyano MD , Pérez-Yarza G , Bringas C , Villarroel Á , Fedetz M , Arellano R , Cortes JM , Martínez L .

	Figure 1. Calcium-activated chloride currents in Xenopus laevis oocyte.Three prototype experimental Cl− currents obtained from the same cell at different conditions: (a) pH 5.0 (n10), (b) pH 7.0 (n11), (c) pH 9.0 (n12). Each chloride time series has 130,000 points (sampling interval 2 milliseconds), which correspond to a period of time of 260,000 milliseconds duration. The vertical axis (Φ) corresponds to the measures of currents in nanoampers (nA).
	Figure 2. Ca2+-dependent Cl− current validation.(a) Xenopus oocyte held at either −60, −40, −20 or 0 mV. Reversal potential of oscillatory currents corresponded to a value close to −23 mV. (b) Oscillatory current reversal potential were dependent on external Cl− concentration, traces show currents in oocytes held at −30 mV or 0 mV in 3 different solutions containing 100%, 50% or 0% Cl−, reversal potential shifted toward more positive potentials as external Cl− concentration decreased. (c) Cytoplasmic injection of EGTA, a Ca2+ chelator, completely eliminated the oscillatory Cl− current.
	Figure 3. Root mean square fluctuation analysis applied to experiment 1 on a single window.Log-log plot of the rms fluctuation F versus l step. The red points depict the results of the original data for each value of l, while the black lines represent the regression lines. (a) α = 0.88 (n1), (b) α = 0.92 (n2) and (c) α = 0.83 (n3). Corresponding (respectively) R2 adjustment coefficients were 0.9915, 0.9921 and 0.9976. The high values of α and R2 indicate non-trivial long-term correlations for each chloride time series during 10, 13 and 12 seconds respectively.
	Figure 4. Long-term correlations across different windows lengths.(a) Global average versus different values of lmax (varying from 1 to 24 seconds). (b) as a function of lmax (varying from 25 to 40 seconds). The error bars represent the standard deviation at each step. It can be observed that all Cl− time series change from positive to negative correlation near lmax = 28 seconds.
	Figure 5. Hurst exponents obtained by the bdSWV analysis.(a) The slope of a log-log plot of the versus the window size for a bdWSV applied to an evoked chloride series (n13, experiment 5, pH = 5.0) gives H = 0.104, indicating the presence of long-term memory. (b) The slope of a log-log plot of the SD(n) versus the window size for a Dispersion Analysis applied to shuffled time series obtained by randomly permuting all the 130,000 time points for each Cl− time series (n13). After shuffling, H was close to 0.5, indicating the disappearance of the memory structure. (c) In red, Hurst exponent values of all the experimental chloride time series; in blue, 100 Hurst exponent values obtained from shuffled series.

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