Visual Stimulus Intensity Research Articles

Old and new versions of the Molyneux question: A review of experimental answers

The ‘Molyneux problem’ is typically framed in terms of the crossmodal matching of shape information from touch to vision. Indeed, shape along with intensity have commonly been considered amodal stimulus properties/dimensions (at least by developmental researchers). However, it is important to note that what is common, if anything, to the senses differs in the two cases: It is the physical stimulus (and possibly also the associated phenomenology) that is thought to be the same in the case of crossmodal (or intermodal) shape matching between touch and vision, whereas it is the nature of the underlying neural encoding that is said to be similar in the case of crossmodal matching of auditory and visual stimulus intensity. While the first empirical data to have been published on these two forms of putatively amodal crossmodal matching appeared to suggest that they both emerge surprisingly early in the course of human development (i.e., within the first month of life), certain of these seminal findings have proved difficult to replicate. Ultimately, therefore, there is currently little convincing evidence to support the notion that such putatively innate crossmodal matching of amodal stimulus dimensions is actually different in kind from the various other crossmodal correspondences that are seemingly acquired at various points during the course of human development (typically as a result of the internalization of the crossmodal statistics of the environment). As such, there may be nothing particularly special about the type of crossmodal matching thought to underlie the ‘Molyneux problem’, and continued interest in the issue may inadvertently have helped to sustain a misguided account of the differences between different types of crossmodal correspondence.

Visual stimulus structure, visual system neural activity, and visual behavior in young human infants.

In visual perception and information processing, a cascade of associations is hypothesized to flow from the structure of the visual stimulus to neural activity along the retinogeniculostriate visual system to behavior and action. Do visual perception and information processing adhere to this cascade near the beginning of life? To date, this three-stage hypothetical cascade has not been comprehensively tested in infants. In two related experiments, we attempted to expose this cascade in 6-month-old infants. Specifically, we presented infants with two levels of visual stimulus intensity, we measured electrical activity at the infant cortex, and we assessed infants' preferential looking behavior. Chromatic saturation provided a convenient stimulus dimension to test the cascade because greater saturation is known to excite increased activity in the primate visual system and is generally hypothesized to stimulate visual preference. Experiment 1 revealed that infants prefer (look longer) at the more saturated of two colors otherwise matched in hue and brightness. Experiment 2 showed increased aggregate neural cortical excitation in infants (and adults) to the more saturated of the same pair of colors. Thus, experiments 1 and 2 taken together confirm a cascade: Visual stimulation of relatively greater intensity evokes relatively greater levels of bioelectrical cortical activity which in turn is associated with relatively greater visual attention. As this cascade obtains near the beginning of life, it helps to account for early visual preferences and visual information processing.

Neuronal Encoding of Emotional Valence and Intensity in the Monkey Amygdala.

Neuropsychological and neuroimaging studies have suggested that the primate amygdala plays an essential role in processing the emotional valence and intensity of visual stimuli, which is necessary for determining whether to approach or avoid a stimulus. However, the neuronal mechanisms underlying the evaluation of emotional value remain unknown. In the present study, we trained male macaque monkeys to perform an operant conditioning task in which fractal visual patterns were associated with three different amounts of air puff delivered to the cheek (negative) or liquid reward (positive). After confirming that the monkeys successfully differentiated the emotional valence and intensity of the visual stimuli, we analyzed neuronal responses to the stimuli in the amygdala. Most amygdala neurons conveyed information concerning the emotional valence and/or intensity of the visual stimuli, and the majority of those conveying information about emotional valence responded optimally to negative stimuli. Further, some amygdala neurons conveyed information related to both emotional valence and intensity, whereas a small portion conveyed information related to emotional intensity alone. These results indicate that the primate amygdala encodes both emotional valence and intensity, highlighting its important role in the avoidance of dangerous stimuli and animal survival.SIGNIFICANCE STATEMENT Evaluating the emotional value of visual stimuli is essential for animal survival, especially in primates. Emotional value is estimated from the emotional valence and intensity of stimuli, and evidence indicates that the amygdala is likely to play a major role in processing these types of information. To our knowledge, the current study is the first to examine the responses of neurons in the monkey amygdala to visual stimuli that differ in emotional valence and intensity simultaneously. Our data suggest that the amygdala plays an important role in the evaluation of emotional stimuli and in the decision to escape negative and harmful stimuli.

Task-dependent audiovisual temporal sensitivity is not affected by stimulus intensity levels

Flexibility and robustness of multisensory temporal recalibration is paramount for maintaining perceptual constancy of the surrounding natural world. Different environments impart various impediments, distances and routes that alter the propagation times of sight and sound cues comprising a multimodal event. One’s ability to rapidly calibrate and account for these external variations allows for maintained perception of synchrony which is crucial for coherent and consistent perception. The two common paradigms used to compare precision of temporal processing between experimental and control groups, the simultaneity judgment (SJ) and temporal order judgment (TOJ) tasks, often use supra-threshold stimuli. However, few studies have specifically examined the effects of normalizing stimulus intensities to participant’s unisensory detection thresholds. The current project presented multiple combinations of auditory and visual stimulus intensity levels, based on individual detection thresholds, during a TOJ and a SJ task. While no effect of stimulus intensity was found on temporal sensitivity or perceived temporal synchrony, there was a significant difference in point of subjective simultaneity (PSS) measures between tasks. In addition, PSS estimates were audio-leading, rather than visual-leading as previously reported, suggesting that exposure to the particular combinations of stimulus intensity levels used influenced temporal synchrony perception. Overall, these results support the use of supra-threshold stimuli in TOJ and SJ tasks as a way of minimizing the confound from differences in unisensory processing.

العلاقة بین کثافة المثیرات المنخفضة بالمحتوى الالکترونی القائم على المعلومات الرسومیة والأسلوب المعرفی على تنمیة التحصیل بمهارات إنتاج مصادر التعلم الرقمیة لدى طلاب کلیة التربیة

هدف البحث الحالي إلى تنمية مهارات إنتاج مصادر التعلم الرقمية لدى طلاب کلية التربية من خلال التعرف على العلاقة بين مستوى کثافة المثيرات البصرية المنخفضة بالمحتوى الالکتروني والأسلوب المعرفي على تنمية مهارات إنتاج مصادر التعلم الرقمية، وقد اتبع البحث المنهج شبه التجريبي لمناسبة طبيعة البحث وتمثلت أدوات القياس في الاختبار التحصيلي، وتم تطبيق هذا البحث في الفصل الدراسي الأول للعام الجامعي 2018-2019م، وقد توصلت نتائج البحث إلى حدوث نمو واضح ودال في جانب التحصيل المرتبط بالجانب المعرفي بمهارات إنتاج مصادر التعلم الرقمية لدى طلاب المجموعة التجريبية الأولى ذوي نمط التعلم المعتمد ؛ وذلک نتيجة لکثافة المثيرات المنخفضة بالمحتوى الالکتروني القائم على المعلومات الرسومية، وحدث نمو واضح ودال في التحصيل بمهارات إنتاج مصادر التعلم الرقمية لدى طلاب المجموعة التجريبية الثانية ذوي نمط التعلم المستقل؛ وذلک نتيجة لکثافة المثيرات المنخفضة بالمحتوى الالکتروني القائم على المعلومات الرسومية، بالإضافة إلى حدوث نمو واضح ودال في التحصيل بمهارات إنتاج مصادر التعلم الرقمية لدى طلاب التجريبية الثانية (مجموعة نمط التعلم المستقل) أکثر من طلاب المجموعة التجريبية الأولى (مجموعة نمط التعلم المعتمد) ؛ وذلک نتيجة للتأثير الأساسي لاستخدام کثافة المثيرات المنخفضة بالمحتوى الالکتروني القائم على المعلومات الرسومية (المتغير المستقل). The aim of the current research is to develop the skills of producing digital learning resources among students of the College of Education through identifying the interaction between the level of low intensity of visual stimuli in E- content and the cognitive method on developing the skills of producing digital learning resources. The research followed the semi-experimental approach to suit the nature of the research. Achievement test, and this research was applied in the first semester of the academic year 2018-2019 AD, and the results of the research revealed a clear growth in the achievement aspect related to the cognitive aspect of the skills of producing digital learning resources among students of the first experimental group with an approved learning style. This is as a result of the low intensity of stimuli in electronic content based on graphic information, and there has been a clear and indicative growth in the attainment of the skills of producing digital learning resources among students of the second experimental group with an independent learning style. This is due to the low intensity of stimuli in electronic content based on graphic information, in addition to a clear growth event indicative of the achievement of digital learning resource production skills among students of the second experimental (the independent learning style group) more than the students of the first experimental group (the adopted learning style group); This is due to the main effect of using the low intensity of stimuli in electronic content based on graphic information (independent variable)..

A quantitative analysis of the contribution of melanopsin to brightness perception

In the retina, intrinsically photosensitive retinal ganglion cells (ipRGCs) which express photopigment melanopsin have been identified as photoreceptors which differ from cones and rods. It has been established that such melanopsin-expressing RGCs are involved in the circadian photo-entrainment and pupillary light reflexes. An additional projection from ipRGCs to the lateral geniculate nucleus has been identified, which indicates the association of ipRGCs with visual perception induced by the image-forming pathway. Reportedly, ipRGCs modulate brightness perception but quantitative analysis of brightness perception involving melanopsin and cones-based signals has not been elucidated. We conducted brightness perception experiments that involved melanopsin using a novel projector with six primary colors and formulated the results for melanopsin and cone stimuli. The white visual stimuli (5 degrees in size) that we used had a single xy-chromaticity values but melanopsin stimuli were modulated by designing different spectral distributions. Perceived brightness was measured using a magnitude estimation method at several luminance levels in the near periphery (7 degrees). Additionally, pupil diameter was measured for estimating the intensity of visual stimuli on the retina. The results showed that the perceived brightness of a white visual stimulus with different spectral distributions can be described by a summation of the nearly linear melanopsin response and the non-linear cone response with weighted coefficients, and the contribution ratio of melanopsin in brightness perception increased to 50% and more with increasing visual stimulus. These suggest that melanopsin signals play a crucial role in the estimation of the absolute intensity of the light environment by obtaining absolute brightness information even when cones are adapted by light.

FRACTAL-BASED ANALYSIS OF THE INFLUENCE OF COLOR TONALITY ON HUMAN EYE MOVEMENTS

An important category of studies in vision science is related to the analysis of the influence of environmental changes on human eye movement. In this way, scientists analyze human eye movement in different conditions using different methods. An important category of works is devoted to the decoding of eye reaction to color tonality. In this research for the first time, we examined the application of fractal theory for decoding of eye reaction to variations in color intensity of visual stimuli. Three green visual stimuli with different color intensities have been applied to subjects and accordingly the fractal dimension of their eye movements has been analyzed. We also tested the eye movement in non-stimulation condition (rest). Based on the obtained results, increasing the color intensity of visual stimuli caused a lower complexity in subject’s eye movement. We also observed that eye movement is less complex in case of non-stimulation compared to different stimulation conditions. The application of fractal theory in analysis of eye movement can be extended to analyze the effect of other stimulation conditions on eye movement to investigate about the decoding behavior of human eye, which is very important in vision science.

Audio-Visual Integration in a Redundant Target Paradigm: A Comparison between Rhesus Macaque and Man.

The mechanisms underlying multi-sensory interactions are still poorly understood despite considerable progress made since the first neurophysiological recordings of multi-sensory neurons. While the majority of single-cell neurophysiology has been performed in anesthetized or passive-awake laboratory animals, the vast majority of behavioral data stems from studies with human subjects. Interpretation of neurophysiological data implicitly assumes that laboratory animals exhibit perceptual phenomena comparable or identical to those observed in human subjects. To explicitly test this underlying assumption, we here characterized how two rhesus macaques and four humans detect changes in intensity of auditory, visual, and audio-visual stimuli. These intensity changes consisted of a gradual envelope modulation for the sound, and a luminance step for the LED. Subjects had to detect any perceived intensity change as fast as possible. By comparing the monkeys' results with those obtained from the human subjects we found that (1) unimodal reaction times differed across modality, acoustic modulation frequency, and species, (2) the largest facilitation of reaction times with the audio-visual stimuli was observed when stimulus onset asynchronies were such that the unimodal reactions would occur at the same time (response, rather than physical synchrony), and (3) the largest audio-visual reaction-time facilitation was observed when unimodal auditory stimuli were difficult to detect, i.e., at slow unimodal reaction times. We conclude that despite marked unimodal heterogeneity, similar multisensory rules applied to both species. Single-cell neurophysiology in the rhesus macaque may therefore yield valuable insights into the mechanisms governing audio-visual integration that may be informative of the processes taking place in the human brain.

Effect of induced high myopia on functional MRI signal changes

PurposeThe current study evaluated the effect of lens-induced high myopia (IHM) on the activity of the occipital visual cortex during two visual stimuli presentations to the subjects. This was done by measuring the Blood Oxygenation Level Dependent (BOLD) signal using functional MRI (fMRI). MethodsBOLD contrast fMRI was performed with a 1.5T MRI scanner on 12 emmetropic subjects (refractive error <±0.25Diopter) with no history of neurologic disorder. IHM conditions were applied to subjects by three convex lenses of +5D, +7D and +10D. Visual stimuli with 0.34cpd and 1.84cpd spatial frequencies (SF) were presented as a block paradigm to the participants in three IHM states and normal vision state during fMRI data acquisition. Resultant fMRI data were compared among different refractive states. ResultsData analysis showed that IHM did not cause a significant change in the visual cortex activity throughout the presentation of 0.34cpd SF visual stimulus and BOLD signal intensity remained approximately constant (p=0.17). Although, fMRI responses to visual stimuli with spatial frequency of 1.84cpd demonstrated that visual cortex activity was significantly reduced in IHM states compared to normal vision (p=0.01), the results showed no significant differences between three different values of IHM. ConclusionsThis study shows severe blurring caused by lens induced high myopia can decrease BOLD signal intensity depending on the visual stimulus pattern details. However in the low and moderate range of spatial frequencies, blur increment from +5D up to +10D is not associated with further reduction in the BOLD signal of the occipital visual cortex.

Self-motion sensitivity to visual yaw rotations in humans.

While moving through the environment, humans use vision to discriminate different self-motion intensities and to control their actions (e.g. maintaining balance or controlling a vehicle). How the intensity of visual stimuli affects self-motion perception is an open, yet important, question. In this study, we investigate the human ability to discriminate perceived velocities of visually induced illusory self-motion (vection) around the vertical (yaw) axis. Stimuli, generated using a projection screen (70 × 90 deg field of view), consist of a natural virtual environment (360 deg panoramic colour picture of a forest) rotating at constant velocity. Participants control stimulus duration to allow for a complete vection illusion to occur in every single trial. In a two-interval forced-choice task, participants discriminate a reference motion from a comparison motion, adjusted after every presentation, by indicating which rotation feels stronger. Motion sensitivity is measured as the smallest perceivable change in stimulus intensity (differential threshold) for eight participants at five rotation velocities (5, 15, 30, 45 and 60 deg/s). Differential thresholds for circular vection increase with stimulus velocity, following a trend well described by a power law with an exponent of 0.64. The time necessary for complete vection to arise is slightly but significantly longer for the first stimulus presentation (average 11.56 s) than for the second (9.13 s) and does not depend on stimulus velocity. Results suggest that lower differential thresholds (higher sensitivity) are associated with smaller rotations, because they occur more frequently during everyday experience. Moreover, results also suggest that vection is facilitated by a recent exposure, possibly related to visual motion after-effect.

P.3.b.006 Event-related potentials in first-episode schizophrenia patients: relationship with clinical data and psychopharmacotherapy

Auditory and visual stimulus intensity levels were manipulated systematically in separate conditions to assess the influence of these variables on the P300 event-related brain potential (ERP). Increases in stimulus intensity produced increases in P300 amplitude and decreases in peak latency for both modalities, although the latency effects were stronger for visual stimulation. Similar, somewhat weaker stimulus intensity effects also were observed for the N100, P200, and N200 components. The findings suggest that stimulus intensity contributes to both P300 amplitude and latency measures in important ways and are discussed in relation to the use of ERPs in applied contexts.

Effects of strobe light stimulation on postnatal developing rat retina

The nature and intensity of visual stimuli have changed in recent years because of television and other dynamic light sources. Although light stimuli accompanied by contrast and strength changes are thought to have an influence on visual system development, little information is available on the effects of dynamic light stimuli such as a strobe light on visual system development. Thus, this study was designed to evaluate changes caused by dynamic light stimuli during retinal development. This study used 80 Sprague-Dawley rats. From eye opening (postnatal day 14), half of the rats were maintained on a daily 12-h light/dark cycle (control group) and the remaining animals were raised under a 12-h strobe light (2 Hz)/dark cycle (strobe light-reared group). Morphological analyses and electroretinogram (ERG) were performed at postnatal weeks 3, 4, 6, 8, and 10. Among retinal neurons, tyrosine hydroxylase-immunoreactive (TH-IR, dopaminergic amacrine cells) cells showed marked plastic changes, such as variations in numbers and soma sizes. In whole-mount preparations at 6, 8, and 10 weeks, type I TH-IR cells showed a decreased number and larger somata, while type II TH-IR cells showed an increased number in strobe-reared animals. Functional assessment by scotopic ERG showed that a-wave and b-wave amplitudes increased at 6 and 8 weeks in strobe-reared animals. These results show that exposure to a strobe light during development causes changes in TH-IR cell number and morphology, leading to a disturbance in normal visual functions.

An alternative theoretical approach to escape decision-making: the role of visual cues.

Escape enables prey to avoid an approaching predator. The escape decision-making process has traditionally been interpreted using theoretical models that consider ultimate explanations based on the cost/benefit paradigm. Ultimate approaches, however, suffer from inseparable extra-assumptions due to an inability to accurately parameterize the model's variables and their interactive relationships. In this study, we propose a mathematical model that uses intensity of predator-mediated visual stimuli as a basic cue for the escape response. We consider looming stimuli (i.e. expanding retinal image of the moving predator) as a cue to flight initiation distance (FID; distance at which escape begins) of incubating Mallards (Anas platyrhynchos). We then examine the relationship between FID, vegetation cover and directness of predator trajectory, and fit the resultant model to experimental data. As predicted by the model, vegetation concealment and directness of predator trajectory interact, with FID decreasing with increased concealment during a direct approach toward prey, but not during a tangential approach. Thus, we show that a simple proximate expectation, which involves only visual processing of a moving predator, may explain interactive effects of environmental and predator-induced variables on an escape response. We assume that our proximate approach, which offers a plausible and parsimonious explanation for variation in FID, may serve as an evolutionary background for traditional, ultimate explanations and should be incorporated into interpretation of escape behavior.

Responses of Rabbit Visual Cortex Neurons to Changes in the Orientation and Intensity of Visual Stimuli

We report here studies of changes in the numbers of spikes in the early phasic discharges (50–90 msec from the moment of stimulus substitution) of neurons in the primary visual cortex of conscious rabbits in response to substitution of lines of different orientations (0–90°) but flashing at constant intensity on a screen, to substitution of lines of constant orientation but different intensities, and to substitutions of complex stimuli in which simultaneous changes were made to the orientation and intensity. Factor analysis of the results showed that the number of spikes in the early phasic discharges of some neurons allowed the two-dimensional sensory space of orientations to be reconstructed. This space was identified in 13 of the 43 neurons studied (30%). Five of the 30 cells studied (16.7%) showed both two-dimensional orientation sensory spaces and two-dimensional intensity spaces. Achromatic spaces were reconstructed by substituting lines of different intensity but constant orientation. On substitution of complex stimuli (intensity + orientation), four stimuli with initial orientations of 0–38.58° (0° corresponding to a vertical line) had an intensity of 5 cd/m2, while the other four stimuli (with orientations of 51.44–90°) were presented at an intensity of 15 cd/m2. On the plane of the sensory space formed by the first two significant factors, the two groups of stimuli with different intensities were located in opposite quadrants of a circle, while within the groups the stimuli were ordered in a sequence close to the order of increases in their slope angles, from smaller angles to greater. It is suggested that in this version, a single sensory plane space reflects the interaction between the orientation and intensity attributes of the visual stimulus, the intensity factor being predominant. A total of seven such cells were found among the 57 studied (12%).

Evoked Potentials in the Rabbit Visual Cortex Reflect Changes in Line Orientation and Intensity

Changes in the amplitudes of evoked potentials in the visual cortex of conscious rabbits in response to substitution of flashing lines of different orientations (0-90 degrees ) but constant intensity were studied, along with interneurons of different intensities but constant orientation, and complex stimuli with simultaneous changes in flash orientation and intensity. Factor analysis of the results showed that analysis of the N85 peak of evoked potentials produced by substitution of stimuli with different orientations but constant intensity identified a two-dimensional sensory space for orientations. An achromatic sensory space was also detected using substitution of lines of different intensities but constant orientation. Substitution of complex stimuli involved two versions of the experiment. In the first version, four stimuli in the initial orientations (0-38.58 degrees ) had an intensity of 5 cd/m(2), the other stimuli (with orientations of 51.44-90 degrees ) were presented at an intensity of 15 cd/m(2). On the plane of the sensory space formed by the first two significant factors, stimuli with different intensities were located in different quadrants of the circle, while within the quadrants themselves, the stimuli were located in accord with their orientations, from lower values to greater. It is suggested that in this version, an interaction between orientation and intensity attributes was seen on the single plane of the sensory space, with a clear predominance of the intensity factor. The other experimental version also included eight complex stimuli, each complex having its own orientation (one of eight over the range 0-90 degrees ) and intensity (also one of eight, in the range 5-21 cd/m(2)). In all experiments involving substitution of complex stimuli, factor analysis identified three to four significant factors. In the vast majority of cases, only the sensory space plane X1, X2 was found, this being formed by two significant factors. On this plane, the stimuli were located in order of changes in intensity. This may be associated with the fact that rabbits are crepuscular animals, such that stimulus brightness is the most important attribute. However, in some cases, potentials in the rabbit brain also demonstrated simultaneous processing of two visual stimulus attributes, i.e., intensity and orientation. This may be evidence indicating analysis of complex stimuli in the primary visual cortex.

Suppression of visual cortical evoked responses following deprivation of pattern vision in adult mice

The effect of visual loss on the adult neocortex can have significant impact on the success of a visual implant. Recent research has shown that the adult neocortex retains substantial plasticity following a disruption to its afferent input. The result of these changes may hamper the development of a visual prosthesis if visual sensation cannot be effectively restored by stimulation of the surviving elements of the visual pathway. In order to evaluate further the visual performance of the mammalian adult brain following visual loss, especially the dominant form of blindness in humans, namely loss of pattern vision, we examined the cortical evoked potential of adult mice following 7, 30 and 120 days of visual deprivation via bilateral eyelid suture. Cortical potentials were elicited with a flash visual stimulus or by electrical stimulation of the retina. We found that after 7 days deprivation there was a potentiation of the evoked response while at 30 and 120 days deprivation the visual evoked responses were significantly reduced. Increasing the visual stimulus intensity reduced the effects. The electrical evoked potential demonstrated a corresponding reduction in stimulus threshold at 7 days and a corresponding rise (40-50%) after 30 and 120 days. These findings suggest that the adult brain exhibited significant experience-dependent modifications following visual loss, and the impact depended on the duration of deprivation. Such reduction in visual responsiveness, especially with electrical activation, will need to be taken into account in the development of a visual implant.

Information processing during physical exercise: a chronometric and electromyographic study

Choice reaction time (RT) is shorter when participants perform a choice task at the same time as a sub-maximal exercise than when they are at rest. The purpose of the present study was to determine whether such an exercise affects response execution or whether it alters processes located upstream from the neuro-muscular level. To this end, the electromyographic (EMG) activity of the response agonists was analysed in a between-hand choice RT task performed either concurrently with a pedalling task or at rest. Visual stimulus intensity was also manipulated so as to determine whether exercise further affects early sensory processes. Results shows that exercise affected the time interval elapsing from the onset of the contraction of the response agonists to the mechanical response, thereby indicating that this variable modifies the peripheral motor processes involved in response execution. EMG signal analyses further revealed that the cortico-spinal command is more efficient during exercise than at rest. In addition, exercise was shown to interact with visual stimulus intensity on the time between stimulus and voluntary EMG onset and to increase the critical flicker fusion frequency threshold, thereby indicating that exercise modifies the peripheral sensory processes involved in early sensory operations. The decomposition of RT, with respect to the EMG activity of response agonists, sheds light on the processes affected by exercise and suggests that exercise affects both sensory processes and late motor processes.

Visualization of neural activity in the rat visual cortex with intrinsic optical imaging

The main objective of this study is to establish an intrinsic optical imaging method for visualizing functional architecture in the in vivo rodent visual cortex. For this purpose, we first determined the three optimal recording conditions for the imaging, viz., the depth of a focal plane, the wavelength of cortical illumination light, and the intensity of visual stimuli. Next, under the optimal recording conditions, we attempted to visualize the monocular (Oc1M) and binocular zones (Oc1B) in the primary visual cortex. The edges of differentially activated domains observed in the optical imaging corresponded to the boundary between Oc1M and Oc1B determined by a histochemical analysis. In addition, we successfully visualized a part of the extrastriate cortex (Oc2L). On the basis of these results, we concluded that we established the method for visualizing functional architecture in the in vivo rodent visual cortex using the intrinsic optical imaging technique. This method is expected to be useful for the assessment of the possible effects of genetic manipulation on the formation of functional architecture in the rodent visual cortex.

Reproducibility of pain measurement and pain perception

The reproducibility of both the conscious experience of pain and the reproducibility of psychophysical assessments of pain remain critical, yet poorly characterized factors in pain research and treatment. To assess the reproducibility of both the pain experience and two methods of pain assessment, 15 subjects evaluated experimental heat pain during four weekly sessions. In each session, both brief (5 s) and prolonged (90 s) heat stimuli were utilized to determine effects of stimulus duration on reproducibility. Multiple presentations of the brief heat stimuli in each session were used to evaluate effects of response averaging. Both visual analog scales (VAS) and randomized verbal descriptor scales (VDS) were employed to better distinguish variations in the pain experience from variations in pain scale usage. Subjects also rated the intensity of visual stimuli in order to provide an independent assessment of the session-to-session variation in the use of both types of scales. Within-subjects analyses revealed that ratings of visual stimuli exhibited significantly less session-to-session variation than ratings of heat pain. Thus, pain perceptions were more variable than perceptions of visual stimuli after controlling for session-to-session variations in scale usage. Comparisons between scales indicated that intensity ratings acquired with the VAS had significantly smaller session-to-session variation than those acquired with the VDS, although VDS ratings were spread across a larger range of the scale. For both scales, analyses of the effects of stimulus averaging and stimulus duration revealed that averaging multiple assessments of the same stimulus substantially reduces session-to-session variation and that multiple assessments of brief stimuli produce responses which are more reproducible than a single presentation of a prolonged stimulus. However, the VAS was significantly more sensitive to small differences in perceived pain intensity and pain unpleasantness, and did not exhibit some of the order effects present with the VDS. Taken together, these results indicate that the reproducibility of psychophysical ratings of pain can be maximized: (1) by averaging responses to multiple, brief stimuli; (2) by providing subjects with a training period distinct from the study period; and (3) by ensuring that interpretation of scale parameters remains constant over time. Thus, although the experiences of both experimental and clinical pain are highly variable, pain assessment procedures can be structured to minimize session-to-session variability.

P300, stimulus intensity, and modality

Auditory and visual stimulus intensity levels were manipulated systematically in separate conditions to assess the influence of these variables on the P300 event-related brain potential (ERP). Increases in stimulus intensity produced increases in P300 amplitude and decreases in peak latency for both modalities, although the latency effects were stronger for visual stimulation. Similar, somewhat weaker stimulus intensity effects also were observed for the N100, P200, and N200 components. The findings suggest that stimulus intensity contributes to both P300 amplitude and latency measures in important ways and are discussed in relation to the use of ERPs in applied contexts.