During prolonged fixation, visual objects presented in the periphery of the visual field often fade from awareness. This phenomenon, known as the Troxler effect, has been largely attributed to adaptation of neurons responding to peripheral targets. Here, we hypothesized that perceptual disappearance might result from degeneration of feedback from attention-related cortical areas to early visual areas, and that visual transients disrupt the feedback loop sustaining low-level signals and thereby trigger perceptual fading. We examined this hypothesis by briefly disrupting the functions of attention-related regions in the intraparietal sulcus (IPS) using transcranial magnetic stimulation (TMS). The hypothesis predicted that temporary disruption of IPS would trigger perceptual disappearances. We measured perceptual disappearance using a task in which participants were asked to discriminate the presence or absence (fading) of a peripheral green target immediately after a TMS pulse. On half of trials the target remained on the screen until the end of a trial, and on the other half of trials it gradually faded. The results of this experiment show that brief disruption of the IPS with a single pulse TMS is sufficient to trigger perceptual disappearance. TMS over the IPS resulted in a fewer reports of continuous percepts (i.e. more fading) without changes in the perception of physically fading stimuli. Our control experiment shows the loss of sensitivity is not due to suppression of microsaccades in response to the sound produced by TMS. Our present study supports the idea that conscious visual perception requires a coupling between the early visual areas representing sensory data and the parietal areas subserving spatial localisation functions.