30 research outputs found
Human cones appear to adapt at low light levels: Measurements on the red—green detection mechanism
AbstractRecent physiological evidence suggests that cones do not light adapt at low light levels. To assess whether adaptation is cone-selective at low light levels, the red-green detection mechanism was isolated. Thresholds were measured with a large test flash, which stimulated the L and M cones in different fixed amplitude ratios, on different colored adapting fields. Thresholds were plotted in L and M cone contrast coordinates. The red-green mechanism responded to an equally-weighted difference of L and M cone contrast on each colored field, demonstrating equivalent, Weberian adaptation of the L and M cone signals. The L and M cone signals independently adapted for illuminance levels as low as 60 effective trolands (e.g. M-cone trolands. Since this adaptation is entirely selective to cone type, it suggests that the cones themselves light-adapt. The red-green detection contour on reddish fields was displaced further out from the origin of the cone contrast coordinates, revealing an additional sensitivity loss at a subsequent, spectrally-opponent site. This second-site effect may arise from a net “red” or “green” signal that represents the degree to which the L and M cones are differently hyperpolarized by the steady, colored adapting field. Such differential hyperpolarization is compatible with equivalent, Weberian adaptation of the L and M cones
How Coupling Determines the Entrainment of Circadian Clocks
Autonomous circadian clocks drive daily rhythms in physiology and behaviour.
A network of coupled neurons, the suprachiasmatic nucleus (SCN), serves as a
robust self-sustained circadian pacemaker. Synchronization of this timer to the
environmental light-dark cycle is crucial for an organism's fitness. In a
recent theoretical and experimental study it was shown that coupling governs
the entrainment range of circadian clocks. We apply the theory of coupled
oscillators to analyse how diffusive and mean-field coupling affects the
entrainment range of interacting cells. Mean-field coupling leads to amplitude
expansion of weak oscillators and, as a result, reduces the entrainment range.
We also show that coupling determines the rigidity of the synchronized SCN
network, i.e. the relaxation rates upon perturbation. %(Floquet exponents). Our
simulations and analytical calculations using generic oscillator models help to
elucidate how coupling determines the entrainment of the SCN. Our theoretical
framework helps to interpret experimental data
Spectral responses of the human circadian system depend on the irradiance and duration of exposure to light
10.1126/scitranslmed.3000741Science Translational Medicine23131ra33
Long Pulse Fusion Physics Experiments without Superconducting Electromagnets
Long-pulse fusion physics experiments can be performed economically via resistive electromagnets designed for thermally steady-state operation. Possible fusion experiments using resistive electromagnets include long-pulse ignition with deuterium-tritium fuel. Long-pulse resistive electromagnets are alternatives to today's delicate and costly superconductors. At any rate, superconducting technology is now evolving independent of fusion, so near-term superconducting experience may not ultimately be useful
On the coherence function for stochastic systems
Coherence function, van der Pol system, Duffing system, 93A25, 93E30,