Onset Of Flash Research Articles

Beyond the point of no return: effects of visual distractors on saccade amplitude and velocity.

Visual transients, such as a bright flash, reduce the proportion of saccades executed, ∼60-125 ms after flash onset, a phenomenon known as saccadic inhibition (SI). Across three experiments, we apply a similar time-course analysis to the amplitudes and velocities of saccades. Alongside the expected reduction of saccade frequency in the key time period, we report two perturbations of the "main sequence": one before and one after the period of SI. First, saccades launched between 30 and 70 ms, following the flash, were hypometric, with peak speed exceeding that expected for a saccade of similar amplitude. This finding was in contrast to the common idea that saccades have passed a "point of no return," ∼60 ms before launching, escaping interference from distractors. The early hypometric saccades observed were not a consequence of spatial averaging between target and distractor locations, as they were found not only following a localized central flash (experiment 1) but also following a spatially generalized flash (experiment 2). Second, across experiments, saccades launched at 110 ms postflash, toward the end of SI, had normal amplitude but a peak speed higher than expected for that amplitude, suggesting increased collicular excitation at the time of launching. Overall, the results show that saccades that escape inhibition following a visual transient are not necessarily unaffected but instead, can reveal interference in spatial and kinematic measures.

Estimating Joule heating and ionic conductivity during flash sintering of 8YSZ

Sintering is a crucial processing step used in a wide variety of fields. Flash sintering is a recent technique to quickly densify conductive ceramics in the presence of an electric field. Full densification can occur in seconds and at low temperatures. However, the mechanisms responsible for such extreme densification rates remain a matter of debate. We provide evidence that Joule heating sets off a chain of events resulting in flash sintering of 8% yttria-doped zirconia (YSZ). We show that prior to flash onset, Joule heating raises sample temperature relative to the thermal equilibrium established with the furnace. Flash sintering occurs once the sample temperature is high enough to cause densification. We derive an empirical model to estimate the conductivity of 8YSZ during flash sintering. We show that the model is equally valid under constant heating rate and in isothermal conditions, regardless of applied electric field strength.

Vagal withdrawal during hot flashes occurring in undisturbed sleep

Little is known about the impact of hot flashes on cardiac autonomic regulation, particularly vagal control. Therefore, we assessed the cardiac autonomic profile associated with physiological hot flashes occurring in undisturbed sleep. Eleven perimenopausal women (45-56 y) had overnight laboratory recordings of polysomnography, electrocardiography, and skin conductance. Eighteen hot flashes that occurred in stable non-rapid eye movement sleep undisturbed by arousals were analyzed. Heart rate variability measures were obtained for three consecutive 2-minute windows starting from 4 minutes before (baseline and preflash periods) to 2 minutes after the onset of hot flashes (hot flash period). Heart rate increased by, on average, 4 beats/minute with the occurrence of a hot flash compared with both baseline (P < 0.001) and preflash (P < 0.001). High-frequency power was reduced, reflecting a decrease in vagal activity, at the onset of a hot flash compared with baseline (P < 0.001) and preflash (P < 0.001). There was no change in sympathovagal balance with the onset of a hot flash. The magnitude of the hot flash (ie, skin conductance amplitude) was associated with increased heart rate (r = 0.78, P < 0.001) and decreased vagal tone (r = -0.56, P = 0.014). Physiological hot flashes per se, recorded during undisturbed sleep periods and independent of any arousals, are associated with increased heart rate and decreased cardiac autonomic vagal activity. These data support the hypothesis that the parasympathetic branch of the autonomic nervous system is involved in the cardiac response to a hot flash.

Relationship between objectively recorded hot flashes and sleep disturbances among breast cancer patients

The aim of this study was to evaluate the relationship between various characteristics of objectively recorded hot flashes and sleep disturbances in breast cancer patients. Fifty-six women who had completed a similar treatment protocol for a first diagnosis of breast cancer within the previous 3 months wore ambulatory sternal skin conductance and polysomnography devices for a home-based nighttime recording of hot flashes and sleep. Hot flash frequency was not associated with polysomnographic variables (r = -0.18 to 0.21) or beta-I and beta-II electroencephalographic activities (r = -0.01 and 0.03) but was significantly correlated with increased slow (r = 0.28) and delta (r = 0.32) electroencephalographic activities. A slower hot flash onset and a longer hot flash duration were associated with greater polysomnographic impairments (r = -0.50 to 0.48). Greater sleep disturbances were found during hot flash onset or hot flash plateau as compared with the pre-hot flash period (greater percentage of wake time, lower percentage of stage II sleep, and lower percentage of rapid eye movement sleep, all P values < 0.05). The probability that a stage change to a lighter sleep occurred was significantly greater during hot flash onset (11%) than during hot flash plateau (6%; P = 0.02). This study suggests that the speed and duration of hot flashes would contribute more importantly to sleep alterations than hot flash frequency. Sleep disturbances tend to occur simultaneously with hot flashes, suggesting that these two nocturnal symptoms are manifestations of a higher-order mechanism involving the central nervous system.

Brain blood flow and cardiovascular responses to hot flashes in postmenopausal women

This study tested two related hypotheses: (1) brain blood flow is reduced during postmenopausal hot flashes, and (2) the magnitude of this reduction in brain blood flow is greater during hot flashes when blood pressure is reduced. Eleven healthy, normotensive postmenopausal women rested in a temperature-controlled laboratory (∼ 25°C) for approximately 120 minutes while waiting for a hot flash to occur. The onset of a hot flash was objectively identified by an abrupt increase in sternal sweat rate (capacitance hygrometry). Middle cerebral artery blood velocity (MCAv; transcranial Doppler) and mean arterial pressure (Finometer) were measured continuously. Each hot flash was divided into eight equal segments, and the segment with the largest reduction in MCAv and mean arterial pressure was identified for each hot flash. During experimental sessions, 25 hot flashes occurred (lasting a mean [SD] of 6.2 [2.8] min, with a mean frequency of 3 [1] hot flashes per participant). Seventy-six percent of hot flashes were accompanied by a clear reduction (>5%) in brain blood flow. For all hot flashes, the mean maximal decrease in MCAv was 12% (9%) (7 [6] cm s). This value did not correlate with corresponding changes in mean arterial pressure (R = 0.36). These findings demonstrate that hot flashes are often accompanied by clear reductions in brain blood flow that do not correspond with short-term reductions in mean arterial blood pressure.

Conscious updating is a rhythmic process

As the visual world changes, its representation in our consciousness must be constantly updated. Given that the external changes are continuous, it appears plausible that conscious updating is continuous as well. Alternatively, this updating could be periodic, if, for example, its implementation at the neural level relies on oscillatory activity. The flash-lag illusion, where a briefly presented flash in the vicinity of a moving object is misperceived to lag behind the moving object, is a useful tool for studying the dynamics of conscious updating. Here, we show that the trial-by-trial variability in updating, measured by the flash-lag effect (FLE), is highly correlated with the phase of spontaneous EEG oscillations in occipital (5-10 Hz) and frontocentral (12-20 Hz) cortices just around the reference event (flash onset). Further, the periodicity in each region independently influences the updating process, suggesting a two-stage periodic mechanism. We conclude that conscious updating is not continuous; rather, it follows a rhythmic pattern.

A flash-drag effect in random motion reveals involvement of preattentive motion processing

The flash-drag (FDE) effect refers to the phenomenon in which the position of a stationary flashed object in one location appears shifted in the direction of nearby motion. Over the past decade, it has been debated how bottom-up and top-down processes contribute to this illusion. In this study, we demonstrate that randomly phase-shifting gratings can produce the FDE. In the random motion sequence we used, the FDE inducer (a sinusoidal grating) jumped to a random phase every 125 ms and stood still until the next jump. Because this random sequence could not be tracked attentively, it was impossible for the observer to discern the jump direction at the time of the flash. By sorting the data based on the flash's onset time relative to each jump time in the random motion sequence, we found that a large FDE with a broad temporal tuning occurred around 50 to 150 ms before the jump and that this effect was not correlated with any other jumps in the past or future. These results suggest that as few as two frames of unpredictable apparent motion can preattentively cause the FDE with a broad temporal tuning.

A flash-drag effect in random motion reveals involvement of preattentive motion processing.

The flash-drag effect (FDE) refers to the phenomenon in which the position of a stationary flashed object in one location appears shifted in the direction of motion in another location in the visual field. Over the past decade, it has been debated how bottom-up and top-down processes contribute to this illusion. In this study we demonstrate that randomly phase-shifting gratings can produce the FDE. In the random-motion sequence we used, the FDE inducer (a sinusoidal grating) jumped to a random phase every 125 ms and stood still until the next jump. Because this random sequence could not be tracked attentively, it was impossible for the observer to discern the jump direction at the time of the flash. By sorting the data based on the flash's onset time relative to each jump time in the random-motion sequence, we found that a large FDE with a broad temporal tuning occurred around 50 to 150 ms before the jump and that this effect was not correlated with any other jumps in the past or future. These results suggest that only two frames of apparent motion stimuli can preattentively cause the FDE with a broad temporal tuning. In the next experiment, we isolated two-frame apparent motion stimuli from the random-motion sequence we used previously, and measured the FDE by presenting the flash at various timings relative to the jump. Under this condition, observers could easily identify the direction of motion. We found the FDE again with a similar temporal tuning, but its amplitude was substantially larger than the effect originally found with the random-motion sequence. Overall, the results of this study suggest that the FDE involves preattentive motion processing but that top-down processes may also be involved in facilitation of the FDE.

Mechanisms of cutaneous vasodilation during the postmenopausal hot flash

Menopausal hot flashes can seriously disrupt the lives of symptomatic women. The physiological mechanisms of the hot flash efferent responses, particularly in the cutaneous circulation, are not completely understood. The aim of this study was to examine the mechanisms of increases in skin blood flow during the postmenopausal hot flash in symptomatic women. Healthy postmenopausal women rested in a temperature-controlled laboratory while responses before and during hot flashes were recorded for three unique protocols. In protocols 1 and 2, women were locally pretreated with an intradermal injection of botulinum toxin A (BTX; blocks the release of neurotransmitters from sympathetic cholinergic nerves) in the forearm (protocol 1) and in the glabellar region (protocol 2). In protocol 3, skin sympathetic nerve activity from the peroneal nerve was recorded, along with skin blood flow and sweating within the region innervated by that neural signal. Skin blood flow was indexed using laser-Doppler flowmetry at the BTX-treated and adjacent untreated control sites. The onset of a hot flash was objectively identified as a transient and pronounced increase in sternal sweat rate. The increases in forearm (protocol 1) and glabellar skin (protocol 2) blood flow during hot flashes were attenuated at the BTX sites relative to the adjacent untreated sites (P<0.05 for both protocols). In protocol 3, skin sympathetic nerve activity significantly increased during hot flashes and returned to pre-hot flash levels after the hot flashes. Increases in skin blood flow during postmenopausal hot flashes are neurally mediated primarily through BTX-sensitive nerves, presumably sympathetic cholinergic.

Inhibition of Steady-State Smooth Pursuit and Catch-Up Saccades by Abrupt Visual and Auditory Onsets

It is known that visual transients prolong saccadic latency and reduce saccadic frequency. The latter effect was attributed to subcortical structures because it occurred only 60-70 ms after stimulus onset. We examined the effects of large task-irrelevant transients on steady-state pursuit and the generation of catch-up saccades. Two screen-wide stripes of equal contrast (4, 20, or 100%) were briefly flashed at equal eccentricities (3, 6, or 12°) from the pursuit target. About 100 ms after flash onset, we observed that pursuit gain dropped by 6-12% and catch-up saccades were entirely suppressed. The relatively long latency of the inhibition suggests that it results from cortical mechanisms that may act by promoting fixation or the deployment of attention over the visual field. In addition, we show that a loud irrelevant sound is able to generate the same inhibition of saccades as visual transients, whereas it only induces a weak modulation of pursuit gain, indicating a privileged access of acoustic information to the saccadic system. Finally, irrelevant changes in motion direction orthogonal to pursuit had a smaller and later inhibitory effect.

Sounds Move a Static Visual Object

BackgroundVision provides the most salient information with regard to stimulus motion, but audition can also provide important cues that affect visual motion perception. Here, we show that sounds containing no motion or positional cues can induce illusory visual motion perception for static visual objects.Methodology/Principal FindingsTwo circles placed side by side were presented in alternation producing apparent motion perception and each onset was accompanied by a tone burst of a specific and unique frequency. After exposure to this visual apparent motion with tones for a few minutes, the tones became drivers for illusory motion perception. When the flash onset was synchronized to tones of alternating frequencies, a circle blinking at a fixed location was perceived as lateral motion in the same direction as the previously exposed apparent motion. Furthermore, the effect lasted at least for a few days. The effect was well observed at the retinal position that was previously exposed to apparent motion with tone bursts.Conclusions/SignificanceThe present results indicate that strong association between sound sequence and visual motion is easily formed within a short period and that, after forming the association, sounds are able to trigger visual motion perception for a static visual object.

Alternation of Sound Location Induces Visual Motion Perception of a Static Object

BackgroundAudition provides important cues with regard to stimulus motion although vision may provide the most salient information. It has been reported that a sound of fixed intensity tends to be judged as decreasing in intensity after adaptation to looming visual stimuli or as increasing in intensity after adaptation to receding visual stimuli. This audiovisual interaction in motion aftereffects indicates that there are multimodal contributions to motion perception at early levels of sensory processing. However, there has been no report that sounds can induce the perception of visual motion.Methodology/Principal FindingsA visual stimulus blinking at a fixed location was perceived to be moving laterally when the flash onset was synchronized to an alternating left-right sound source. This illusory visual motion was strengthened with an increasing retinal eccentricity (2.5 deg to 20 deg) and occurred more frequently when the onsets of the audio and visual stimuli were synchronized.Conclusions/SignificanceWe clearly demonstrated that the alternation of sound location induces illusory visual motion when vision cannot provide accurate spatial information. The present findings strongly suggest that the neural representations of auditory and visual motion processing can bias each other, which yields the best estimates of external events in a complementary manner.

Contributions of visible persistence and perceptual set to the flash-lag effect: Focusing on flash onset abolishes the illusion

Among other theories, visible persistence has been suggested to explain the flash-lag effect (FLE). According to this account, the flash is not compared to the moving object at its perceived onset, but at a later time while it is still subjectively visible. Therefore, it is reported to lag the moving object. We show that observers’ perceptual set determines whether the persisting image of the flash or its onset is used to judge relative position. Spontaneously, observers use the persisting image, such that a flash-lag results. When forced to focus on the onset of the flash because flashes and stationary onset-only stimuli are mixed, observers base their judgments on the onset and the FLE is abolished. We found that perceptual set affected the FLE in the flash-initiated and in the continuous-motion paradigm. Finally, we showed that the position of the moving object was perceived without any blur and that the flash persisted subjectively for at least 60–80 ms. Changes of perceptual set and visible persistence may underlie many of the previously reported modulations of the FLE.

Local motion inside an object affects pointing less than smooth pursuit

During smooth pursuit eye movements, briefly presented objects are mislocalized in the direction of motion. It has been proposed that the localization error is the sum of the pursuit signal and the retinal motion signal in a ~200 ms interval after flash onset. To evaluate contributions of retinal motion signals produced by the entire object (global motion) and elements within the object (local motion), we asked observers to reach to flashed Gabor patches (Gaussian-windowed sine-wave gratings). Global motion was manipulated by varying the duration of a stationary flash, and local motion was manipulated by varying the motion of the sine-wave. Our results confirm that global retinal motion reduces the localization error. The effect of local retinal motion on object localization was far smaller, even though local and global motion had equal effects on eye velocity. Thus, local retinal motion has differential access to manual and oculomotor control circuits. Further, we observed moderate correlations between smooth pursuit gain and localization error.

Cutaneous and hemodynamic responses during hot flashes in symptomatic postmenopausal women

The aim of this study was to test the hypothesis that the postmenopausal hot flash is accompanied by rapid decreases in arterial blood pressure and increases in cutaneous vascular conductance (CVC), as evaluated by continuous measurements of these variables in symptomatic women. Twelve healthy, normotensive, postmenopausal women rested in a temperature-controlled laboratory (26 degrees C) for approximately 90 minutes. The onset of a hot flash was objectively identified as a transient and pronounced elevation of sternal sweat rate (capacitance hygrometry). Twenty-three hot flashes were recorded during the experimental sessions (3.4 +/- 1.4 min; range, 1.3-6.5 min). Mean arterial blood pressure decreased 13 +/- 2 mm Hg during 11 hot flashes in five participants. Data from these participants, categorized as responders, were analyzed separately from data for those participants whose blood pressure did not change during their hot flashes (n = 7, 12 hot flashes). Heart rate (obtained from an electrocardiogram) significantly increased during the hot flashes, but there was no difference between the responder and nonresponder groups (9 +/- 2 vs 10 +/- 1 beats/min, respectively; P > 0.05). The increase in CVC was not different between groups at either the forearm (15% +/- 3% vs 12% +/- 3% maximal CVC, P > 0.05) or sternum (24% +/- 5% vs 21% +/- 3% maximal CVC, P > 0.05). These data demonstrate that in a subset of participants, the hot flash is accompanied by a significant reduction in blood pressure, but there is no difference in CVC between these women and women with no drop in blood pressure.

Brain computer interface using flash onset and offset visual evoked potentials

ObjectiveThis paper presents a brain computer interface (BCI) actuated by flash onset and offset visual evoked potentials (FVEPs). Flashing stimuli, such as digits or letters, are displayed on a LCD screen for inducing onset and offset FVEPs when one stares at one of them. Subjects can shift their gaze at target flashing digits or letters to generate a string for communication purposes. MethodsBy designing the flickering sequences with mutually independent flash onsets (or offsets) and employing the inherent property that onset (or offset) FVEPs are time-locked and phase-locked to flash onsets (or offsets) of gazed stimuli, segmented epochs based on the flash onsets (or offsets) of gazed stimuli will be enhanced after averaging whereas those based on the onsets (or offsets) of non-gazed stimuli will be suppressed after averaging. The amplitude difference between the N2 and P2 peaks of averaged onset FVEPs, denoted by Amponset, and that between the N1 and P1 peaks of averaged offset FVEPs, denoted by Ampoffset, are detected during experiments. The stimulus inducing the largest value of the sum Amponset+Ampoffset is identified as the gazed target and the representative digit or letter is sent out. ResultsFive subjects participated in two experiments. In the first experiment, subjects were asked to gaze at 25 flickering stimuli one by one with each for a duration of 1min. The mean accuracy with 10-epoch averages was 97.4%. In the second task, subjects were instructed to generate a string ‘0287513694E’ by staring at stimuli on a pseudo keypad comprising ten digits ‘0–9’ and two letters ‘B’ and ‘E’. The mean accuracy and information transfer rates were 92.18% and 33.65bits/min, respectively. ConclusionsThe onset and offset FVEP-based BCI has shown that high information transfer rate has been achieved. SignificanceA novel FVEP-based BCI system is proposed as an efficient and reliable tool for disabled people to communicate with external environments.

In vivo functional imaging of human cone photoreceptors

We evaluate a novel non-invasive optical technique for observing fast physiological processes, in particular phototransduction, in single photoreceptor cells in the living human eye. The method takes advantage of the interference of multiple reflections within the outer segments (OS) of cones. This self-interference phenomenon is highly sensitive to phase changes such as those caused by variations in refractive index and scatter within the photoreceptor cell. A high-speed (192 Hz) flood-illumination retina camera equipped with adaptive optics (AO) is used to observe individual photoreceptors, and to monitor changes in their reflectance in response to visible stimuli ("scintillation"). AO and high frame rates are necessary for resolving individual cones and their fast temporal dynamics, respectively. Scintillation initiates within 5 to 10 ms after the onset of the stimulus flash, lasts 300 to 400 ms, is observed at visible and near-infrared (NIR) wavelengths, and is highly sensitive to the coherence length of the imaging light source. To our knowledge this is the first demonstration of in vivo optical imaging of the fast physiological processes that accompany phototransduction in individual photoreceptors.

Auditory–visual multisensory interactions attenuate subsequent visual responses in humans

Effects of multisensory interactions on how subsequent sensory inputs are processed remain poorly understood. We investigated whether multisensory interactions between rudimentary visual and auditory stimuli (flashes and beeps) affect later visual processing. A 2×3 design varied the number of flashes (1 or 2) with the number of beeps (0, 1, or 2) presented on each trial, such that ‘2F1B’ refers to the presentation of 2 flashes with 1 beep. Beeps, when present, were synchronous with the first flash, and pairs of stimuli within a trial were separated by 52 ms ISI. Subjects indicated the number of flashes presented. Electrical neuroimaging of 128-channel event-related potentials assessed both the electric field strength and topography. Isolation of responses a visual stimulus that was preceded by a multisensory event was achieved by calculating the difference between the 2F1B and 1F1B conditions, and responses to a visual stimulus preceded by a unisensory event were isolated by calculating the difference between the 2F0B and 1F0B conditions (MUL and VIS, respectively). Comparison of MUL and VIS revealed that the treatment of visual information was significantly attenuated ∼160 ms after the onset of the second flash when it was preceded by a multisensory event. Source estimations further indicated that this attenuation occurred within low-level visual cortices. Multisensory interactions are ongoing in low-level visual cortices and affect incoming sensory processing. These data provide evidence that multisensory interactions are not restricted in time and can dramatically influence the treatment of subsequent stimuli, opening new lines of multisensory research.

The dual-peak light response of ganglion cells in chicken retina

In the present study, a particular temporal pattern of the ganglion cells' light response specified as “dual-peak” was observed. In the chicken retina ( N = 15), about 37.5% (174 out of 464) of the ganglion cells showed such special temporal property in response to the onset of light flash. These neurons responded to light stimulus with two successive components: a transient increase of firing rate which lasted for less than 100 ms, and another prolonged light response appeared in about 100 ms after the first transient response. Moreover, our data demonstrated a temporal adaptation process in the later phase of firing activities when repeated flashes were applied. Meanwhile, the earlier phase had a more stable latency in response to the stimulus. Application of picrotoxin could evoke the dual-peak responses in transient ganglion cells. These results suggest that the origination of the two response components might be distinct and the later one is likely related to GABAergic pathways.

Visual evoked potential actuated brain computer interface: a brain-actuated cursor system

Flash visual evoked potential (FVEP), induced by OFF-to-ON flash, i.e. flash onset, in a light emitting diode (LED) was used to control four cursor movements (left, right, up, down), and left- and right-button clicks on a screen menu. ON or OFF duration in each flashing sequence was designed to be random so that all flashing sequences were mutually independent. Since FVEPs are time-locked and phase-locked to flash onsets of gazed LEDs, segmenting EEG signals based on the flash onsets of each flashing sequence followed by averaging will sharpen epochs evoked by gazed LEDs. Four inexperienced subjects were asked to generate a sequence of cursor commands. Mean recognition and transfer rates were 88% and 3.74 s/command, respectively.