key: cord-0701195-9swrz8a7
authors: García Cena, Cecilia; Costa, Mariana Campos; Saltarén Pazmiño, Roque; Santos, Cristina Peixoto; Gómez-Andrés, David; Benito-León, Julián
title: Eye Movement Alterations in Post-COVID-19 Condition: A Proof-of-Concept Study
date: 2022-02-14
journal: Sensors (Basel)
DOI: 10.3390/s22041481
sha: 3ef40689e7a1b63a5bec1d999e2d2de4a4b29964
doc_id: 701195
cord_uid: 9swrz8a7

There is much evidence pointing out eye movement alterations in several neurological diseases. To the best of our knowledge, this is the first video-oculography study describing potential alterations of eye movements in the post-COVID-19 condition. Visually guided saccades, memory-guided saccades, and antisaccades in horizontal axis were measured. In all visual tests, the stimulus was deployed with a gap condition. The duration of the test was between 5 and 7 min per participant. A group of [Formula: see text] patients with the post-COVID-19 condition was included in this study. Values were compared with a group ([Formula: see text]) of healthy volunteers whom the SARS-CoV-2 virus had not infected. Features such as centripetal and centrifugal latencies, success rates in memory saccades, antisaccades, and blinks were computed. We found that patients with the post-COVID-19 condition had eye movement alterations mainly in centripetal latency in visually guided saccades, the success rate in memory-guided saccade test, latency in antisaccades, and its standard deviation, which suggests the involvement of frontoparietal networks. Further work is required to understand these eye movements’ alterations and their functional consequences.

The measurement of eye movement and its alteration arises as a powerful marker to diagnose brain functionality. Several studies support this fact. For instance, in [1] [2] [3] [4] [5] [6] [7] [8] [9] [10] [11] [12] [13] [14] [15] [16] [17] provide scientific pieces of evidence related to particular alterations of eye movement in multiple neurological disorders, such as Alzheimer's disease (AD), Parkinson's disease (PD), multiple sclerosis (MS), and autism, among others. For example, patients with AD not only have higher latency and latency variability regardless of the tasks, but also show more incorrect antisaccades and take more time to correct them, which has been suggested as an early marker of AD [3] [4] [5] [6] [7] . In PD and some other parkinsonian syndromes, patients may present eye movement alterations, such as hypometria, abnormally fragmented saccades (multistep or staircase saccades), and considerable difficulty in inhibiting the saccade movement reflex during the antisaccade test. Furthermore, in patients with moderate or

A saccadic movement, or saccades, is defined as a rapid jerk-like movement of the eyes that direct the gaze to a new location and redeploy the region of high visual acuity centered on the fovea [32] . Saccades are regarded as voluntary movements, but are generally produced with highly automated routines. For further information related to the neurological aspects of eye movements, the reader is referred to [33] .

A commercial, binocular and wearable gaze tracker was used to record the eye movements. A picture of this gaze tracker model is shown in Figure 1 [34] .

This whole system weighs around 22.75 g, and its dimensions are 160 mm × 51 mm × 175 mm. While the world camera is used to capture the image of the whole visual field of the user, each eye camera records the pupil position using infrared light. In this setup, the world camera operates at 30 Hz and each eye camera at 200 Hz with a resolution of 1080 × 1080 px and 192 × 192 px, respectively. According to user manual data, the gaze accuracy is 0.60º with a precision of 0.02º [35] . Moreover, the technical parameters reported by the manufactured turns it suitable for this proof-of-concept. The subject wearing the gaze tracker was seated in front of the monitor with his/her head in the chin rest. We used a chin rest to keep the head still to avoid disturbance in the measurement of eye movements. The chin rest was placed at 60 cm from the monitor used to deploy the visual stimulus. The center of the monitor and the user's line of sight were coincident as much as possible. The monitor was connected by an HDMI/VGA cable to a computer (ASUS VivoBook laptop CORE i7 8th Gen, in this specific case), while the Pupil Core eye-tracking glasses were also connected to the same laptop via USB-C cable. Figure 2 shows a scheme of the system setup. Notice that corrective glasses and make-up have to be removed. The video-oculography system was calibrated before the recording using the calibration software provided by the manufacturer. It consisted of the onset of the stimulus in five different positions on the screen: the center and the four corners. The targets remained in each position for a few seconds while the pupil was automatically detected and that particular position of the gaze recorded.

In order to generate the battery of visual stimulus, it was used an open-source software called PsychoPy [36, 37] . It is a free cross-platform package that allows running a wide range of experiments in the behavioral sciences (neuroscience, psychology, psychophysics, and linguistics, among others). It is a community project, so users have all the source code available to develop a new application. Moreover, it has a flexible and intuitive Builder Interface to develop a new experiment through a Python code or using the resources available in the application such as texts, icons, and figures, among others.

It is worth emphasizing that Pupil software and PsychoPy software are manually synchronized, then the user is encouraged to stay quiet and not move the head after the calibration. Room lights were turned off to enhance the quality of the captured image by the gaze tracker. The procedure is outlined in Figure 3 . 

Based on previous studies [3, [38] [39] [40] [41] [42] and as well as in authors expertise [2, 16, [43] [44] [45] [46] , in this proof of concept, it was decided to test the horizontal axis to validate the potential of the eye movement as a biomarker for the brain functionality in the post-COVID-19 condition.

In order to assess saccadic movements, there are three methods: the gap where the fixation point disappears prior to the onset of the visual stimulus; the shift where the offset of the fixation point and the onset of the visual stimulus happen simultaneously; and the overlap paradigms where the fixation point and the visual stimulus are overlapped in time before the offset of the former [47] [48] [49] [50] .

Saccadic latency is defined as the time (in milliseconds) from target appearance to saccade initiation of correct trials. Latency value is task dependant. In fact, there are several studies reporting these differences [5, 17, [51] [52] [53] [54] [55] [56] [57] [58] [59] [60] . Perhaps, the most significant factor in reducing the reaction time, in terms of both the magnitude and robustness of the reduction, occurs in a phenomenon known as the gap. In a typical gap effect study, participants are asked to fixate on a centrally located fixation point and then make a saccade, as quickly as possible, to a suddenly appearing peripheral target. Several pieces of research justify the use of "gap" in attention and memory assessments such as.

This study implemented three visual tests under gap conditions: visually guided saccades, memory-guided saccades, and antisaccades. A calibration process was carried out before each test to ensure the accuracy of the measurement. As a stimulus, a blue circle with a diameter of 3 mm was selected, and the screen background was configured in dark black color. The stimulus location was ±5 • , ±17 • and ±22 • . In all tests, the position of the stimulus (left or right, as well as the target amplitude) was randomized, and the gap duration was three seconds. In the following section, details related to each paradigm test are mentioned.

As shown in Figure 4 , the visual stimulus appears in the center of the screen (0, 0) and jumps, randomly, towards a new position and, after three seconds, returns to the center. The whole duration of the test was one minute, and this process was repeated ten times. In this test, variables like latency towards the stimulus, latency back to the center of the screen, number of blinks, and performance were measured. 

In this test, the working memory [61, 62] was assessed. We instructed to the subject to make a prosaccade during the first stimulus's onset and then to remember this position in order to do a memory saccade in the dark period. Figure 5 summarizes this procedure: the visual stimulus appears in the center of the screen, after 3 s, the stimulus jumps randomly to right or left, with unpredictable eccentricity, ±5 • , ±17 • and ±22 • and returns to the screen's center. After that, the participant must remember the last position of the visual stimulus and generate a voluntary eye movement towards it, but in the absence of a stimulus. The whole duration of the test is two minutes, and variables such as blinks and success rate in the memory saccade are computed. 

Similar to the horizontal visually guided saccade test, in the antisaccade test, the stimulus appears first in the center and then in random positions for three seconds in both cases. However, the participant is encouraged to look at the opposite position of the visual stimulus. This process is repeated ten times, and the whole duration of the test is one minute. In Figure 6 , a scheme of antisaccade test is presented. The performance of the antisaccade test requires at least two subprocesses: the ability to suppress a reflexive saccade towards the visual stimulus and the ability to generate a voluntary saccade in the opposite direction to a location without any stimulus. Blinks, success in the antisaccades, the latency of the antisaccades and reflexive antisaccades were calculated. 

This subsection defines the features computed in eye movements tests described in the previous subsection. After recording, each test is processed using the gaze-tracker software that provides binocular gaze positions in both axes, x, and y. Figure 7 shows a scheme with the saccadic movements for each eye. Here, the movement is classified according to the movement itself (adducting or abducting), the visual pathway (temporal or nasal), and the primary position of the eyeball (centrifugal and centripetal). Centripetal saccades are made from the periphery of the orbit to its center (the primary position of the eyeball), while centrifugal saccades are made from the center to the periphery. These saccadic movements involve the adduction and the abduction of the eyeball. Centrifugal latency, t [ms], is defined by the time elapsed between the onset of the periphery stimulus, t s , and the time from the eye moves in response to this stimulus t gaze . It is computed by (1);

Centripetal Latency, t c [ms], is defined by the time elapsed between the onset of the fixation point in the center of the screen, t f ixpoint , and the time from the eye moves in response to it, t gaze . In this case, it is computed by (2);

In [44] was demonstrated the linear relation between age and the t and t c for healthy volunteers, and a model was provided for computing the latency under gap paradigm. That research used the centrifugal and centripetal latencies model to compare the measured values to ensure the measured value's reliability. In (3) and (4), the linear dependency between latency and age in healthy brain aging was demonstrated. According to [16] , Reflexive Saccade is defined by an eye movement in the same direction of the stimulus, in the antisaccade test (see Figure 8b ). The Success Rate in antisaccade test or in memory guided test is defined by the correct movement according to the test (opposite side in antisaccade and remember position in memory test, respectively).

When the centripetal latency, t c , is between 70 ms and 130 ms, the eye movement is usually referred to as express saccade [63] and is driven by the subcortical retinotectal pathways [64] . In contrast, the "normal" saccades are driven by the thalamocortical pathway, which projects to the parietal eye field and then to the superior colliculus [65] , so express saccade is not included in mean values.

This study did not include measurements of dysmetrias and related variables and asymmetries in the movement (differences between eyes).

A group of ten patients with the post-COVID-19 condition was consecutively selected from the Patient Affected by COVID-19 Disease Association (AMACOVID), Madrid. None reported having a neurological disease previous to COVID-19. One of the subjects was excluded after the data analysis due to noise in the measurement; therefore, nine participants (three men and six women) were included in the analyses. The patients with the COVID-19 condition had a mean (±standard deviation) age of 49.56 ± 9.14 years, weight of 74.33 ± 19.29 kg, and height of 164.0 ± 7.27 cm. On the other hand, a group of healthy volunteers matched by age was recruited as a control group. These subjects had not been diagnosed with COVID-19 disease nor had previous neurological diseases [44] . See Table 1 for details. Table 2 shows the most relevant demographic and clinical characteristics of post-COVID-19 patients. Table 3 summarizes the clinical picture suffered by the patients upon the diagnosis, including the diagnosis date. COVID-19 diagnosis was confirmed by SARS-CoV-2 reverse transcription-polymerase chain reaction of a nasopharyngeal swab. Three patients were infected during the first wave (February to 1 June 2020), four were infected during the second wave (2 June 2020-9 December 2020), and the remaining two during the third wave (10 December 2020-15 March 2021). The most common clinical picture was febrile illness followed by cough and pneumonia. Patients' other symptoms were hair and skin problems, headache, anorexia, and diarrhea, among others. Table 4 summarizes the symptoms suffered by patients after COVID-19. The majority of them present complaints of fatigue or memory disturbance. Other symptoms reported were anosmia and shortness of breath. Patients VAMA02 and VAMA03 mentioned abnormal heart rhythms, such as arrhythmias and tachycardia, respectively. On the other hand, VAMA03 had edemas of the lower limbs and VAMA10 skin rash; hair loss was reported in both patients. This last patient also complained of hand pain and VAMA06 that had limb weakness. In addition, VAMA03 had speech problems and hand pain. VAMA06 had limb weakness as well. 

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Tables 5-7 present the computed eye movement's features described in previous section. Table 5 shows the minimum, maximum, and mean value of the latency, as well as the value computed by the model given by Equations (3) and (4). By computing the absolute error in each measurement, we found that this error ranged between 8 × 10 −2 and 6 × 10 −3 ms; hence, the values measured with the portable gaze tracker had the accuracy needed to compute latency. Average antisaccade error rates in healthy humans vary considerably across studies and laboratories, with some studies reporting rates as low as 5% and others as high as 25% [66, 67] . Some studies [68, 69] using large samples suggest an error rate of around 20% is typical. Error rates are not constant across the lifespan, being highest during childhood, reaching the lower rates during early adulthood, and then increasing very slowly with advancing age until around 55-60, when the rate of increase appears to accelerate [44] . The latency values depend on the target location tested as well as the method to assess it (gap, step or overlap) [70] . Several studies report the values of latency in visually guided saccade test with a large number of volunteers [71] [72] [73] [74] . By comparing results given in Table 7 with those previously reported, we found similar latency values. According to memory-guided saccades and antisaccades tests, parameters measured from group G1 were in the range of those previous studies related to the success of the ocular tasks [44, 75, 76] . The main conclusion here is that the gaze-tracker is helpful for this proof of concept.

By considering the eye movement battery described in the previous section, the main results are presented in Tables 8-10 . According to this, and by comparing them with those previously studies [18, 77, 78] , these patients had eye movement alterations.

Two patients had latencies out of the normal range for their age (VAMA02 and VAMA10). Considering the success rate in the memory-guided saccade test, three patients showed abnormal success rates (VAMA05, VAMA06, and VAMA10), less than 50%. In the antisaccade test, the total number of correct eye movements (opposite to the stimulus) were according to the normality; however, three patients had a poor performance in the inhibitory capabilities (VAMA02, VAMA06, and VAMA10). Furthermore, the latency of the antisaccades was proper of healthy volunteers in the range of 65-85 years old [44] . The number of blinks was also higher than healthy volunteers in all tests. 

Although the sample size in both groups was small, we checked the statistical significance of the features. Firstly, variables were classified as parametric or non-parametric. Most part of the values shown in Tables 5-10 are expressed as the mean value and the standard deviation. Differences between groups were analyzed using t-test for parametric variables while Kruskal-Wallis test followed by Dunn's test for non-parametric variables. This analysis was performed using MatLab.

There were significant differences among groups when p-value was less than 0.05. After this, significative variables were: centripetal latency in visually guided saccades (p-value < 0.05), the success rate in memory-guided saccade test had a p-value < 0.05, blinks in whole test (p-value < 0.02), latency in antisaccades (p-value < 0.001) and its standard deviation (p-value <0.001). Although the p-value for the centrifugal latency was not significant (>0.05), it could be due to the small sample size.

In this study, we have reported the eye movement alterations in a group of post-COVID-19 patients. Despite the gaze tracker was not certified as a medical device, the computed values from the gaze position given by the gaze tracker were in agreement with the literature (see Section 3). Therefore, the gaze-tracker and the software developed to assess the main features are valid.

According to [70] , using monocular recordings of eye movement in monocular viewing conditions or binocular recordings in binocular viewing conditions leads to asymmetries in the retina and the optic nerve, which affects saccadic eye movements, meanly in peak velocity than other parameters [79] . This study measured binocular eye movements and compared results with other studies done in binocular viewing conditions. The values measured reveal that patients who have suffered COVID-19 have eye movement alterations of interest, as these alterations are similar to those reported for mild cognitive impairment or Alzheimer's disease [3] [4] [5] [6] [7] 9, 11, 12, 15, 16] .

The dorsolateral prefrontal cortex is involved in the development of saccadic eye movements [80] . This structure has direct connections with the main cortical ocular motor areas, namely the frontal eye field and the supplementary eye field in the frontal lobe; several (associative, attentional, and motor) areas in the posterior parietal cortex, including the parietal eye field; the cingulate eye field in the anterior cingulate cortex; and the superior colliculus in the brainstem [80] . For the performance of memory-guided saccades, that is, involving short-term spatial memory, visually guided saccades, and antisaccades, the posterior parietal cortex, the dorsolateral prefrontal cortex, and the frontal eye field play significant roles [80] [81] [82] [83] . We found that patients with the post-COVID-19 condition had eye movement alterations mainly in centripetal latency in visually guided saccades, the success rate in memory-guided saccade test, latency in antisaccades, and its standard deviation, which suggests the involvement of frontoparietal networks. Further work is required to understand these eye movements' alterations and their functional consequences.

The main limitations of our study are the sample size and the age of volunteers. We, however, considered that the sample size was enough for a proof-of-concept study. Likewise, related to the second limitation, the age as well as the sex of the participants were not relevant to demonstrating that SARS-CoV-2 virus infection may affect eye movement performance.

This study aimed to evaluate eye movement alterations using wearable and a commercial gaze-tracker.

We used a chin rest to avoid the influence of head movements on eye movements. In addition, after each visual test, the system was re-calibrated. Furthermore, those ocular features highly dependent on the accuracy were not included, such as gain or dysmetria.

Related to the visual tests, we implemented them using a free software platform under Python. The gap setup was selected because it is widely used to assess memory conditions in other neurological diseases like mild cognitive impairment, AD, or PD, (see Sections 1 and 2).

Our patients still report cognitive complaints that they did not have before COVID-19. Eye movement assessment objectively unveiled the existence of these symptoms. Ongoing, more extensive studies will better understand the impact of COVID-19 on the brain. Informed Consent Statement: Informed consent was obtained from all subjects involved in the study.

The data sets generated during the current study are available from the corresponding author upon reasonable request.

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The authors would like to thank AMACOVID, Asociación Madrileña de Afectados por el COVID-19.

There is no conflict of interest.