Light adaptation of the human photopic oscillatory potentials: Influence of the length of the dark adaptation period

The influence of adaptation on the oscillatory potentials of the human electroretinogram was studied in the domains of frequency and time. The amplitude of OP1 to OP4, the summed amplitude of OP1 to OP4, as well as the area, decreased from dark adaptation to light adaptation. With increasing intensi

Oscillatory potentials were recorded from four adult subjects under dark-and light-adapted conditions with photopically balanced red and blue flashes. The responses between 80 and 200 Hz were analyzed by means of a Fast Fourier transform program. The results show a robust change in the power --but n

Utilizing a high intensity photographic flash unit, electroretinograms were recorded from normal adults under fully light adapted conditions over a 5 log unit range of stimulus luminance (-1.35 to 3.34 log cd-s/m2). At lower luminance levels b-wave amplitude increased with increased luminance until

The oscillatory potentials are viewed by many as small oscillations of a highfrequency domain that ride on the b-wave of the electroretinogram. A study of electroretinograms and oscillatory potentials performed in 25 normal subjects was undertaken to substantiate my claim that oscillatory potentials

The typical vertebrate electroretinogram obtained upon illumination of the eye is a complex polyphasic wave. After a short latent period there appears a small deflection (a-wave)2 indicating a condition of negativity of the posterior portion of the eyeball. This is then followed by a rapid positive