Figure 1

(a) Cultured rat cortical neuron labeled with main structural components. (b), (c) Examples of axonal arc length measurements. Measurements are performed before (b) and after (c) a 5-min wait period. The average velocity is determined from the difference between L1 and L2 divided by the 5-min time interval. The growth description is presented as a one-dimensional probability distribution of the measured velocity.Reuse & Permissions

Figure 2

(a) Time-integrated data of axon elongation rates. Fitting a Laplace distribution yields the mean velocity $v_c$ $=$ 5.1 μm/h and scale parameter 1/κ $=$ 16.7 μm/h. (b) V-shaped velocity-potential obtained from the probability distribution shown in (a) using Eq. (2). Error bars represent a 95$\%$ confidence interval of a binomial distribution.Reuse & Permissions

Figure 3

Theoretical time evolution of axonal velocity distributions that follow an initial truncated Laplace distribution (dotted line) defined in the range (a) [$-$2.5,12.5] and (b) ($-$∞, $-$2.5)∪(12.5, ∞). All units are in μm/h. These initial distributions evolve in time toward the time-independent Laplace distribution given by Eq. (2) [represented by the continuous curves in (a) and (b), respectively]. The time evolution is governed by the Fokker-Planck equation; two intermediate states are shown as dotted-dashed lines in (a) and (b). The diffusion coefficient for axonal growth velocity is determined by fitting these solutions to the corresponding initial subsets in the experimental time-lapse data (see Fig. 4).Reuse & Permissions

Figure 4

Plot of initial measurements for all neurons from all incubation periods (a) before and (b) after limiting observation to specific subset of data, with velocities in the interval [$-$2.5,12.5] μm/h, indicated with arrows. (c) The distribution of velocities for this subset of neurons measured after 5 and (d) 10 min, showing evolution toward a Laplace stationary distribution. Similar behavior is observed for the complementary data set.Reuse & Permissions